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Home My WebLink About2008-04-16 e-packet SPECIAL MEETING CITY COUNCIL OF THE CITY OF SOUTH SAN FRANCISCO P.o. Box 711 (City Hall, 400 Grand Avenue) South San Francisco, California 94083 Meeting to be held at: MUNICIPAL SERVICES BUILDING C()MMUNrry ROOM ::33 ARRC)YO DRIVE WEDNESDAY, APRIL 16, 2008 6:30 P.M. NOTICE IS HEREBY GIVEN, pursuant to Section 54956 of the Government Code of the State of California, the City Council of the City of South San Francisco will hold a Special Meeting on Wednesday, the 16th day of April 2008, at 6:30 p.m., in the Community Room at the Municipal Services Building, 33 Arroyo Drive, South San Francisco, California. Purpose of the meeting: 1. Call to Order. 2. Roll Call. 3. Public Conlments - comments are limited to items on the Special Meeting Agenda. 4. Study Session - Discussion of the findings of the completed cost and construction feasibility study and provision of direction regarding the Oyster Point Marina Concept Plan. 5. Approval of the Junipero Serra Boulevard Remediation Replanting Conceptual Plan. 6. Adjournment. AGENDA ITEM # 4 DATE: April 16, 2008 TO: Honorable Mayor and City Council FROM: Marty Van Duyn, Assistant City Manager SUBJECT: STUDY SESSION - OYSTER POINT MARINA CONCEPT It is recommended that the City Council accept the attached report completed by Kleinfelder titled "Feasibility Study and Cost Estimate - Proposed Oyster Point Marina Redevelopment" and provide direction on the Oyster Point Marina Concept Planning effort. BACKGROUND In the fall of 2006, the City's consultant ROMA Design Group presented a draft of the Oyster Point Concept Plan to the City Council. At that meeting, Council questioned the feasibility of constnlcting a convention center and hotels on the Oyster Point Marina property, which is a closed landfill site over bay mud. Specifically, the feasibility and order of estimated costs of construction on the site in question. Council directed staff to solicit consulting services to determine whether or not the high intensity option is feasible. In April of 2007, City Council authorized the Planning Division to enter into a contract with Kleinfelder to complete the subject study. The study is attached for reference. Kleinfelder was directed to focus on the . high-intensity development concept plan created by ROMA Design Group. Specifically, the task was to provide preliminary geotechnical and environmental conclusions and recommendations for the design of a high density conference center and hotel development at Oyster Point. The study also includes a cost comparison between development at Oyster Point (landfill and bay mud), a Bay Mud site (no landfill), and a "Traditional Solid Ground" site. DISCUSSION Study Conclusions The study concludes that from an environmental and geotechnical standpoint, Oyster Point can be redeveloped with the high density option (convention center and hotels) but there is a significant cost premium associated with this option. The additional costs are related to foundation work that will be necessary for the project, as well as continuing maintenance costs. These additional costs are likely to severely impact the economic viability of this type of project in the foreseeable future. Staff Repoli Subject: City Council Update Feasibility Study Page 2 of 3 Cost Estimates The cost estimates provided in the subject study COlnpare the environmental and geotechnical cost of planned high density development at Oyster Point to both a Bay Mud site (no landfill), and to a "Traditional Solid Ground" site. When compared to a "Traditional Solid Ground" site, the report estimates that the increased cost for both geotechnical and environmental aspects of the high density development option for Oyster Point would be about $33M. This is a 15 percent increase in the total construction costs, relative to a "Traditional Solid Ground" site. When compared to a Bay Mud site, the additional costs are estimated to be $8.5M, or approximately a four percent increase in total construction costs over a "Traditional Solid Ground" site. Leaseholds Most of the land at Oyster Point is controlled by King Ventures, a real estate developer specializing in hospitality (see attached Leaseholds Map). Several leases expire in 2011, but there is a 25 year renewal option. The fact that the eastern two-thirds of Oyster Point is encumbered by long term leases severely limits the redevelopment potential of the Oyster Point Marina area in the short- and medium-term. There is one viable redevelopment site at this time - Parcel A - the former Hilton Hotel site. This site has access to Oyster Point Boulevard and Gull Drive, is located on solid ground, and is well positioned for redevelopment. At this time, staff believes that the Kleinfelder report has provided information that deems the high intensity development option economically unfeasible. Staff also believes that due to the long-term leases that encumber much of Oyster Point (approximately 30 years), and the cost to buyout the leases (rumored to be $8M to $14M), our planning efforts should be limited at this tune. Next Steps Staff is recommending that the Oyster Point Concept Planning effort be put on hold for the time being. Rather than defining a specific land use concept at this time, staff recommends that the City focus on the physical upgrades such as the utility relocation and possibly a new road along the north side of Oyster Point. The utility relocation is required by the Regional Water Quality Control Board to get water, sewer and electrical utilities out of the landfill, and into dedicated and self-contained conduits. Any and all physical improvements that are completed should be consistent with the 'Framework Plan' (attached) that was done as part of the concept planning effort. Further, the design of future engineering projects should be done with input and direction from the City's concept planning consultant, to ensure that current improvements do not hinder the City's future redevelopment plans. CONCLUSION The Kleinfelder study suggests that the high density redevelopment of Oyster Point is feasible from an environmental and geotechnical perspective but not likely from a [mancial perspective. Additionally, the current lease arrangement presents serious timing issues for redevelopment. Therefore, staff recommends that the concept planning for Oyster Point be put on hold and any necessary (legally required) upgrades reflect the concept planning (configuration and layout) work already completed for Oyster Point. Staff Report Subject: City Council Update Feasibility Study Page 3 of 3 By: )"". lJ//1 ......" / ! (;/ fir> /'L . /L (/[~tj Marty Van Duyn Assistant City Manag' r I Attachment: Kleinfelder Report Leaseholds Map Framework Plan BMN/MVD/SK/gb By: .--." ~"-'7-" ) f ::<, \\, . (~f\\.. /1 <<\-L......~j "'''',-. Barry M. Nag.€! ~/ City Manager KlEINFElDER Prepared for the City of South San Francisco FEASIBILITY STUDY AND COST ESTIMATE PROPOSED OYSTER POINT MARINA REDEVELOPMENT SOUTH SAN FRANCISCO, CALIFORNIA COPYRIGHT 2007 KLEIN FELDER ALL RIGHTS RESERVED UNAUTHORIZED USE OR COPYING OF THIS DOCUMENT IS STRICTLY PROHIBITED BY ANYONE OTHER THAN THE CLIENT FOR THE SPECIFIC PROJECT Date: November 12, 2007 File No.: 84166/Geo/Env 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder KlEINfElDER 'In el1lfJ1ovee owned cornp,JI]} November 12, 2007 File: 84166/Geo/Env Mr. Gerry Beaudin Associate Planner City of South San Francisco Department of Economic and Community Development 315 Maple Avenue P.O. Box 711 South San Francisco, California 94083 Feasibility and Cost Marina Redevelopment in South San Francisco, California Dear Mr. Beaudin: Kleinfelder is pleased to submit twenty five copies and an electronic copy of the final report of our feasibility study and cost estimate for the proposed redevelopment of the Oyster Point Marina in South San Francisco, California. The enclosed study provides preliminary geotechnical and environmental conclusions and recommendations for the design and construction of a high density conference center and hotel development option for this project as outlined in our proposal dated February 13, 2007 (BAR7P002). We previously issued an initial administrative draft of this study on August 10, 2007 and a revised administrative draft on October 12, 2007 which addressed comments on the first document. We received comments on the revised administrative draft, and have addressed those comments in this current report. As discussed in our proposal, previous reports prepared by Kleinfelder and others for the subject site have been used to develop feasibility-level recommendations for the current project. Based on our review of the previous geotechnical and environmental studies, we believe the site may be developed as currently proposed. If the project is pursued, further studies including a field exploratory investigation of the site should be performed to confirm the feasibility-level recommendations contained in this report. The conclusions and recommendations presented in this report are based on our review of subsurface explorations performed at the subject site over the last approximately 30 years and other information prepared by others. Variations between anticipated and actual subsurface conditions may exist. Final design documents should not rely exclusively on this report, and construction of this project should not go forth 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder I< LEI N F E L 0 E R 7133 Ko" Center Parkway, Suite 1 00, Pleasanton, CA 94566-3101 (925) 484-1700 (925) 484-5838 fax Page 1 of 2 November 12, 2007 without the completion of a design-level geotechnical and environmental investigation that includes soil borings at the project site. We appreciate the opportunity of providing our services to you on this project and trust this report meets your needs at this time. If you have any questions concerning the information presented, please contact us at (925) 484-1700. Sincerely, KLEINFELDER WEST, INC. Liana Serrano Staff Engineer .0 , C.E., G.E. #2015 I Engineer LS/MH/RJO/MFM/jmk '\ ' J'frtt4;r'; ;/, /"2-%1' /";,t!c~ .' /' tC./ Ll7fit.-~ Mehagan Hopkins Staff Environmental Professional Michael F. Majchrzak, P.E., G.E. #555 Principal G~O;;~~~liR~._~~.(;,:~:". in.e er ~ ~ \'\#"-~=-:-"_'_':~',j'>r~', :'''.' ~ /,.. '" ". '/0 !'\t L f; if .' "', ~;"?,\ . . J:,/.~V1 ./ r ,(\f I Vi/.> --." (/ \ . . f I ~'I- (~':~ ' 7fj~'j \'y:,,,, \. ~r/l..t..j .~' '--,...(.. '\ \ \ ( Cl: ,:,...() " r. f\ . , ' /1,1 r-.l Z \~-( t::: \rO, Sr.- )>)G,)} <~J(p ":II ..) t:- :A;":::;;; (j) (l! . ~~ J' /::;; ~\ 0" ,,/'" ~~~\0<,~ ...~ ~:l1 0\ (-. .......(,.' Ljf<'J I [' f\, \.- .,,/)f,.. ..... 0 .0..../,/' l\'r'-/. .0, ~~~,<~ ~~---,-:"~ \ ~ .,,"'..... (:li "'n\(\~\ 'l~~;~'1... J r\J \ \ 84166 / (PLE7R4 78.doc) / jmk Copyright 2007, Kleinfelder KLEINFELDER 7133 1<011 Center Parkway, Suite 100, Pleasanton, CA 94566-3101 (9251484-1700 (925) 484-5838 fax Page 2 of 2 November 12, 2007 Geotechnical engineers structure their services to meet the specific needs of their clients, A geotechnical engineering study conducted for a civil engi- neer may not fulfill the needs of a construction contractor or even another civil engineer. Because each geotechnical engineering study is unique, each geotechnical engineering report is unique, prepared solelyfor the client. No one except you should rely on your geotechnical engineering report without first conferring with the geotechnical engineer who prepared it. And no one - not even you - should apply the report for any purpose or project except the one originally contemplated. Serious problems have occurred because those relying on a geotechnical engineering report did not read it all. Do not rely on an executive summary. Do not read selected elements only. fA A Geotechnical engineers consider a number of unique, project-specific fac- tors when establishing the scope of a study. Typical factors include: the client's goals, objectives, and risk management preferences; the general nature of the structure involved, its size, and configuration; the location of the structure on the site; and other planned or existing site improvements, such as access roads, parking lots, and underground utilities. Unless the geotechnical engineer who conducted the study specifically indicates oth- erwise, do not rely on a geotechnical engineering report that was: not prepared for you, not prepared for your project, not prepared for the specific site explored, or completed before important project changes were made. Typical changes that can erode the reliability of an existing geotechnical engineering report include those that affect: the function of the proposed structure, as when it's changed from a parking garage to an office building, or fiOm a light industrial plant to a refrigerated warehouse, elevation, configuration, location, orientation, or weight of the proposed structure, composition of the design team, or project ownership. As a general rule, always inform your geotechnical engineer of project changes-even minor ones-and request an assessment of their impact. Geotechnical engineers cannot accept responsibility or liability for problems that occur because their reports do not consider developments of which they were not informed. A geotechnical engineering report is based on conditions that existed at the time the study was performed. Do not rely on a geotechnical engineer- ing report whose adequacy may have been affected by: the passage of time; by man-made events, such as construction on or adjacent to the site; or by natural events, such as floods, earthquakes, or groundwater fluctua- tions. Always contact the geotechnical engineer before applying the report to determine if it is still reliable. A minor amount of additional testing or analysis could prevent major problems. Site exploration identifies subsurface conditions only at those points where subsurface tests are conducted or samples are taken. Geotechnical engi- neers review field and laboratory data and then apply their professional judgment to render an opinion about subsurface conditions throughout the site. Actual subsurface conditions may differ-sometimes significantly- from those indicated in your report. Retaining the geotechnical engineer who developed your report to provide construction observation is the most effective method of managing the risks associated with unanticipated conditions, Do not overrely on the construction recommendations included in your report. Those recommendations are not final, because geotechnical neers develop them principally from judgment and opinion, Geotechnical can finalize their recommendations only by observing actual subsurface conditions revealed during construction, The geotechnical engineer who developed your report cannot assume responsibility or /Jability for the report's recommendations if that engineer does not perform construction observation. Other design team members' misinterpretation of geotechnical engineering reports has resulted in costly problems. Lower that risk by having your geo- technical engineer confer with appropriate members of the design team after submitting the report. Also retain your geotechnical engineer to review perti- nent elements of the design team's plans and specifications. Contractors can also misinterpret a geotechnical engineering report. Reduce that risk by having your geotechnical engineer participate in prebid and preconstruction conferences, and by providing construction observation. Geotechnical engineers prepare final boring and testing logs based upon their interpretation or field logs and laboratory data. To prevent errors or omissions, the logs included in a geotechnical engineering report should never be redrawn for inclusion in architectural or other design drawings. Only photographic or electronic reproduction is acceptable, but recognize that separating logs from the report can elevate risk. Some owners and design professionals mistakenly believe they can make contractors liable for unanticipated subsurface conditions by limiting what they provide ror bid preparation. To help prevent costly problems, give con- tractors the complete geotechnical engineering report, but preface it with a clearly written letter or transmittal. In that letter, advise contractors that the report was not prepared ror purposes of bid development and that the report's accuracy is limited; encourage them to confer with the geotechnical engineer who prepared the report (a modest fee may be required) and/or to conduct additional study to obtain the specific types of information they need or prefer. A prebid conference can also be valuable. Be sure contrac- tors have sufficient time to perform additional study. Only then might you be in a position to give contractors the best information available to you, while requiring them to at least share some of the financial responsibilities stemming from unanticipated conditions. Some clients, design professionals, and contractors do not recognize that geotechnical engineering is far less exact than other engineering disci- plines. This lack of understanding has created unrealistic expectations that have led to disappointments, claims, and disputes. To help reduce the risk of such outcomes, geotechnical engineers commonly include a variety 01 explanatory provisions in their reports, Sometimes labeled "limitations" many of these provisions indicate where geotechnical engineers' responsi- bilities begin and end, to help others recognize their own responsibilities and risks, Read these provisions closely Ask questions, Your geotechnical engineer should respond rully and frankly. The equipment, techniques, and personnel used to perform a geoenviron- mental study differ significantly rrom those used to perform a geotechnical study, For that reason, a geotechnical engineering report does not usually relate any geoenvironmental findings, conclusions, or recommendations; e.g., about the likelihood of encountering underground storage tanks or regulated contaminants, Unanticipated environmental problems have led to numerous project failures. If you have not yet obtained your own geoen- vironmental information, ask your geotechnical consultant for risk man- agement guidance. Do not rely on an environmental report prepared for someone else. Diverse strategies can be applied during building design, construction, operation, and maintenance to prevent significant amounts of mold from growing on indoor surfaces, To be effective, all such strategies should be devised for the express purpose of mold prevention, integrated into a com- prehensive plan, and executed with diligent oversight by a professional mold prevention consultant. Because just a small amount of water or moisture can lead to the development of severe mold infestations, a num- ber of mold prevention strategies focus on keeping building surfaces dry. While groundwater, water infiltration, and similar issues may have been addressed as part of the geotechnical engineering study whose findings are conveyed in this report, the geotechnical engineer in charge of this project is not a mold prevention consultant; the services with Membership in ASFE/The Best People on Earth exposes geotechnical engineers to a wide array of risk management techniques that can be of genuine benefit for everyone involved with a construction project. Confer with you ASFE-member geotechnical engineer for more information. TlI11 lIllst l'lluh llll 'Earth Copyrig/1t 2004 by,4SFE, Inc, Duplication, rrJproduction. or copying of this document, in whole or in part, by any means whatsoever, strictly prohibited, except wit/) ASFE:s specific written permission, Excerpting, quoting, or otherwise .'Jxtracting wording from this document is permitted only with the express written permission of /J.SFE, and only (or pwooses of scholarly research or boo/< review, Only members of ,4SFE may use this document as a complement to or as an element of geotecimical engineering report, Any firm, individual, or other entity t/7at so uses this document without being an ,ASFE member could be committing negligent or intentional (fraudulent) misrepresentation, IlGER06045OM KlEINFELDER 6.5 GROU N D 1M PROVEM ENTS ...................... .... ................ ................................23 6.5.1 Earthwork.... ......... .... ........ .......... ... ... ... ... ... ............ ... .......... ...... ..... ...........23 6.5.2 Pavements............................................................................................... 24 6.5.3 Site Drainage ... ................. ........ .... ......... ... ....... ......... .......... ........ ......... ....25 6.6 LAN D F ILL RE LA TED DES I G N IMP ACT S ..................................................... 26 6.6.1 Building-Soil Interface .............................................................................. 26 6.6.2 Uti I ities. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 27 6.6.2.1 Excavation and Backfill.....................................................................27 6.6.2.2 Building Connections... ......................... ................ ...................... ......27 7 E NVI RON M ENTAL FEASISI LITY..................................... ................ ............... ......30 7 .1 GROUNDWATER MONITORING ................................................................... 30 7.1.1 Current Monitoring and Impacts ........ ....... ...... ..... ........... .......... ................ 30 7.1.1.1 Chemical Sampling and Analysis......................................................30 7.1.1.2 Groundwater Elevation Monitoring....................................................31 7.1.2 Possible Changes with Site Development................................................31 RELOCATION OR REMOVAL.......................................................... 32 7.2. 1. 1 Procedures for Refuse Characterization, Removal and Disposal..... 32 7.3 FINAL COVER. ........ ........... ......................................... .......... ....... ............. .....33 7.3.1 Components of the Cover ........................................................................ 33 7.3.2 Modification of Current Cover...................... ......... ............................... ....34 7.3.3 'Landscaping and Irrigation Aspects .........................................................34 7 .4 LEACHATE MANAGEMENT SYSTEMS ........................................................ 35 7.4.1 Leachate Monitoring.................................................... .............................35 7.4.2 Existing Systems.................. ....................................... .... ............ .............35 7.4.3 Need for Modifications......... .......... ..........................................................36 7.5 LAN D FILL GAS SYSTEMS ...... ............... ...... ........... ... ....... ........ ......... ........... 36 7.5.1 Shielding and Venting .. ........ ..... ............................... ........ ........................ 37 7.5.2 Monitoring................. ........................ ................................................ .......38 7.5.3 Permitting .. ........ .... .... ........ ...... ...... ........................ ...................................39 7.6 CONSTRUCTION CONSIDERATIONS .......................................................... 40 7.6.1 Worker Safety......................... ....... .......... ........ ......... ....... ....... ............. .... 40 7.6.2 Excavations.............. ............ .................................. ..................................40 7.6.2. 1 Permitting............... ...... .... ................................. ........ ........................41 7. 7 OPERATIONS AND MAINTENANCE .............................................................41 7.7.1 Erosion..................................................................................................... 42 7.7.2 Drainage.... ............. ................. .... .............. ......... ... ................ .............. ..... 42 7.7.3 Settlement. ........ ...................... ....... ....... ........ ... ................ ................... ..... 42 7.7.4 Landfill Gas Monitoring System ......... .............................. ......... ............... 42 7. 7.4. 1 Sensor Calibration........... ......................... ..... ........... ..... ...................42 7.7.4.2 Sensor Head Replacement........... .............. .......... ...... ... ........ ...... .....43 7.7.4.3 Battery Replacement............... ............................... ......... ....... ..........43 7.7.4.4 General Inspection ....... ........... ... .... ....... ............ ........ ..... .... ...... .........43 7.7.5 Reporting...... ..................................,................. ................ ........................44 7 .8 REGULATORY COORDINATION .................................................................. 44 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page ii of iv November 12, 2007 KlEINFElDER 8 ESTI MATED COSTS .................. ........................................................................... 45 8.1 SUM MARy............ ......... ..... ........................................... ............................ ..... 45 8.2 GEOTECHNICAL COST ESTIMATES ........................................................... 48 8.2.1 Geotechnical Cost Estimate Summary...... ........ .............. ....... ........... ......48 8.2.2 Pile Foundations ............... .... ........ ........ ..... ...... ...... .......... ..... ............. ... ... 49 8.2.3 Concrete Slab and Pile Caps ..... .......... ....... ........... ....... ...... .... ........... ... ...49 8.2.4 Landfill Related Improvements.................................................................50 8.2.5 Operations and Maintenance................................................................... 50 8.3 ENVIRONMENTAL COST ESTIMATES ......................................................... 50 8.3.1 Environmental Cost Estimate Summary ..................................................50 8.3.2 Construction Cost Basis......................................... .......... ........................51 8.3.3 Monitoring and Reporting.............................. ................. ........ .................. 52 8.3.4 Waste Relocation or Removal .................................................................52 8.3.5 Landfill Gas Mitigation...... ................................................... ..................... 53 8.3.6 Construction Health and Safety...... ........... ...... .... .......... ..... ........ ... ..........53 8.3.7 Operations and Monitoring Plan .... .... .......... ..... ......... ................ ..... ..........53 8.3.8 Monitoring and Reporting............................. .................... ........ ................ 53 8.3.9 Permitting................................................................... ....................... .......54 9 CO N CLU SIONS ....... ..... .......................................... ....... ...................... .......... ........55 10 LI MIT A TION S.... ... ..... .... ........ .................................. ......... .... ....... ........ ...................57 84166/ (PLE7R478.doc) I jmk Copyright 2007. Kleinfelder Page iii of iv November 12, 2007 PLATES Plate 1 Plate 2 Plate 3 Plate 4 Plate 5 Plate 6 Plate 7 TABLES Table 1 Table 2 KlEINFElDER FEASIBiliTY STUDY AND COST ESTIMATE PROPOSED OYSTER POINT MARINA REDEVELOPMENT SOUTH SAN FRANCISCO, CALIFORNIA PLATES, TABLES, AND APPENDICES Site Vicinity Map High Intensity Development Concept Plan Site Plan and Geologic Cross Section Locations Landfill Cap Thickness Contour Map Geologic Cross Sections Bay Mud Thickness Contours Groundwater Elevations and Analytical Concentrations: December 2006 Summary of CIOMB Closure and Post-Closure Requirements, CCR Title 27, Oyster Point Landfill Summary of RWOCB Closure and Post-Closure Requirements, CCR Title 27, Oyster Point Landfill Page iv of iv November 12, 2007 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder KLEINFELDER FEASIBiliTY STUDY AND COST ESTIMATE PROPOSED OYSTER POINT MARINA REDEVELOPMENT SOUTH SAN FRANCISCO, CALIFORNIA 1 EXECUTIVE SUMMARY This study is to provide preliminary geotechnical and environmental conclusions and recommendations for the design and construction of a high density conference center and hotel development option for this project. In addition, a rough cost estimate for development between the Oyster Point site and a site that would be classified as "Traditional Solid Ground" is also provided. The various options being considered for the redevelopment of Oyster Point include a low intensity open space and recreation option, a medium intensity option that is comprised of a combination of smaller one- and two-story buildings and open space, and a high density conference center/hotel option. This study is focused on the high intensity development option as shown on Plate 2, High Intensity Development Concept Plan. Based upon data collected during this investigation, it is our opinion that, from a geotechnical and environmental standpoint, the site can be developed for construction although very high initial foundation costs as well as continuing maintenance may severely impact the economic viability of the project. It is important that the unique and problematic subsurface conditions of this site be properly considered in design. Based on the results of our research into this and similar sites and projects, the primary geotechnical and environmental considerations affecting the project are: 1. Devising a means for mitigating the effects of the extremely large total and differential settlements associated with the decomposition and compression of the refuse material on both the planned structures and on the site improvements. 2. Development of a foundation system capable of transferring the building loads to the weathered bedrock materials underlying the refuse material. 3. Impacts related to landfill gas both during and subsequent to construction activities. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 1 of 58 November 12, 2007 KLEINFELDER 4. High initial costs related to waste relocation, construction health & safety, permitting and installation of equipment, as well as continuing maintenance. 5. Development of the site will likely require the removal of refuse material from the landfill for purposes related to the installation of the foundation piles, installation of the appropriate cap and final site grading. These materials should be re- deposited on site or at an appropriate off-site landfill, and could impact the construction schedule. 6. The soil cap was found to vary from 1 to 14 feet in thickness, a continuous clay layer that is normally associated with a landfill cap was not apparent throughout the site as based on our research. Design and construction must maintain a minimum 4-foot cap including an erosion protection layer. Several areas are deficient in thickness and should be upgraded 7. Monitoring of the site as outlined in the Joint Technical Document should continue following development. We have concluded that a feasible deep foundation alternative to support structures is a system of piles driven into the clays, sands or weathered bedrock materials underlying the Bay Mud. Shallow mat foundations, such as those used for the restroom buildings at the site, may be used for small or lightly loaded structures. Also of primary concern is the mitigation of the problems associated with the differential settlement within the landfill surface and also between the pile supported building and the surrounding soil. Differential settlements are expected to disrupt pavement utilities, and subgrade supported structures even with mitigation measures to reduce differential settlement at the surface incorporated into the design. The design will also have to incorporate provisions to allow for utilities and subgrade supported structures to interface with the pile supported building. Our cost estimate was initially based on comparing the cost of the planned development at Oyster Point to a 'Traditional Solid Ground" site. Because many similar types of projects have been developed along the fringe of the San Francisco Bay over Bay mud, we are also provided a comparison with development at Oyster Point as compared to a Bay mud site. A "Traditional Solid Ground" site would typically be located away from the bay, and the development would be constructed on a shallow 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 2 of 58 November 12, 2007 KlEINFElDER foundation system consisting of isolated and continuous footings that would be about 4 to 5 feet thick. There would be only minor concerns about settlement of the floor slab and site improvements. A Bay mud site would require the use of a deep foundation system (such as driven piles) to support the planned buildings. The system would extend below the existing Bay mud at the site. For our comparison, we have assumed that the thickness of the Bay mud would be equivalent to that encountered at Oyster Point; therefore the same site but without the landfill. There would be some site settlement, which would depend on the amount of fill, but not to the extent as the combination of Bay mud and landfill material at Oyster Point would produce. Both the "Traditional Solid Ground" site, and the Bay mud site were assumed not to have environmental issues. In summary, the increased cost for both geotechnical and environmental aspects of development at Oyster Point, as compared to a "Traditional Solid Ground" site is estimated to be about $33,000,000. This increased cost is equivalent to about a 15 percent increase in costs as compared to a "Traditional Solid Ground" site. For comparison to another site underlain by Bay mud only (no landfill), the increase in cost for developing at Oyster Point is estimated to be about $8,500,000 more. This increased cost is equivalent to about a 4 percent increase as compared to a "Traditional Solid Ground" site. These numbers can be summarized as follows: Traditional site -> Oyster Point = $33,000,000 more (or about 150/0 increase) Bay mud site -> Oyster Point = $8,500,000 more (or about 40/0 increase) The basis of this cost estimated is presented in Section 8, "Estimated Costs" of this report. The basis for our assessment of Oyster Point and a more detailed discussion of our evaluation and conclusions are presented below in the following sections of this report. Additional field exploration and evaluation of the site is needed before more detailed design recommendations can be provided. Among other items, a stability evaluation of the existing levees is needed. 84166 I (PLE7R478.doc) I jmk Copyright 2007, Kleinfelder Page 3 of 58 November 12, 2007 KlEINFElDER 2 INTRODUCTION This feasibility level study presents preliminary conclusions, recommendations and cost estimates for the proposed redevelopment of the Oyster Point Marina in South San Francisco, California. A Site Vicinity Map showing the location of the site is presented on Plate 1. Our preliminary conclusions and recommendations presented in this document are based on a review of published environmental and geotechnical documents previously prepared for the subject property by Kleinfelder and others. The previous reports include subsurface data obtained between 1970 and 2000. Actual site conditions may vary from those anticipated in this report. 2.1 PROJECT DESCRIPTION Various options are being considered for the redevelopment of Oyster Point, including a low intensity open space and recreation option, a medium intensity option that is comprised of a combination of smaller one- and two-story buildings and open space, and a high density conference center/hotel option. Currently, we have been requested to provide a feasibility assessment and order of magnitude cost analysis for the high intensity development option. This report was prepared only for the high intensity development option. This option is shown on Plate 2, High Intensity Development Concept Plan. 2.2 SITE DESCRIPTION The Oyster Point Marina is located at the eastern end of Oyster Point Boulevard in the City of South San Francisco. San Francisco Bay surrounds the site on the north, east, and south sides, with Oyster Point Boulevard and Gull Drive on the west side. This area encompasses approximately 57 acres, and is a former landfill site. The Harbor District currently operates the municipal marina and a park at the site, and manages property leases for other facilities, including public restrooms, office complexes; the Oyster Point Marina Inn, a marine boat sales company, and the Oyster Point Yacht Club (see Site Plane, Plate 3). The site contains paved parking lots and drive aisles. A 84166/ (PLE7R478.doc) / jmk Copyright 2007. Kleinfelder Page 4 of 58 November 12, 2007 KlEINFElDER 3 REVIEW OF PROJECT DOCUMENTS In order to develop information for our feasibility study we reviewed documents provided by the City and also available in Kleinfelder project files pertaining to previous projects at Oyster Point. Our literature review included the following documents: · Geotechnical Investigation for the Proposed Expansion of Oyster Point Marina, South San Francisco, California. Woodward-Clyde Consultants. October 1976. · Environmental Field Investigation Report. Oyster Point Landfill South San Francisco, California. Kleinfelder, Inc. January 7, 1999. . Joint Technical Document - Post-Closure Management of the Oyster Point Landfill, South San Francisco, Volumes 1 and 2. Gabewell with PES Environmental, Inc. March 2000. . Assembly of Supplemental Geotechnical Design Criteria for the Proposed Hilton Hotel at Oyster Point in South San Francisco, California. Kleinfelder, Inc. May 5, 2000. . Final Engineering Report For Site Development Application Proposed Hilton Hotel Site Oyster Point Landfill South San Francisco, California. Kleinfelder, Inc. August 30, 2000. . Final Closure and Post-Closure Maintenance Plan Oyster Point Landfill South San Francisco, California. Gabewell, Inc. with Harding Lawson Associates. September 2000. . Storm Water Pollution Prevention and Monitoring Plan, Oyster Point Landfill South San Francisco, California. Gabewell, Inc. with Harding Lawson Associates. September 2000. . Maximum Allowable Concentration Limits Oyster Point Landfill South San Francisco, California. Gabewell, Inc. with PES Environmental, Inc. July 2004. . Workplan for Supplemental Perimeter Landfill Gas Investigation and, if Necessary, Evaluation of Remedial Alternatives, Former Oyster Point Landfill South San Francisco, California. Terra Engineers, Inc. August 8, 2006 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 8 of 58 November 12, 2007 KLEINFELDER · Annual Reporl 2006, Former Oyster Point Landfill City of South San Francisco, South San Francisco, California. Terra Engineers, Inc. with PES Environmental, Inc. January 30,2007. · Quarlerly Reporl of Landfill Gas Monitoring Results - February 2007. Terra Engineers, Inc. February 24,2007. · Response to Comments on Perimeter Landfill Gas Concentrations and Revised Work Plan - Gull Drive Area Former Oyster Point Landfill, South San Francisco, California. Terra Engineers, Inc. March 29, 2007. . Response to Comments of Revised Work Plan - Gull Drive Area Former Oyster Point Landfill, South San Francisco, California. Terra Engineers, Inc. April 21, 2007. Pertinent data from the above documents was utilized in our study. 84166 / (PLE7R478.doc) / jmk Copyright 2007, KleinfeJder Page 9 of 58 November 12, 2007 KLEINFELDER 4 GEOLOGY AND SEISMICITY 4.1 REGIONAL GEOLOGY The San Francisco Bay Area lies within the Coast Range geomorphic province, a series of discontinuous northwest trending mountain ranges, ridges, and intervening valleys characterized by complex folding and faulting. The general area of Oyster Point is located on the reclaimed baylands along the westerly shores of San Francisco Bay. The bay is underlain by a depressed rock block which is Cenozoic in age, and is wedged between two uplifted blocks featuring the East Bay Hills on the east and the Coastal Range of the San Francisco Peninsula on the west. This series of blocks is associated with the complex zone of the San Andreas fault system. The San Andreas fault is located in the Coastal Ranges along the western edge of the depressed block, and the Hayward fault (located at the base of the East Bay Hills) forms the east delineation of the depressed block. During the geologic period known as the Pleistocene Epoch, when the sea level was lowered approximately 300 feet in the Bay Area due to glacial activity, ravines and canyons were created by erosion in the elevated rock blocks. Alluvial debris was washed onto the depressed bedrock areas forming the alluvial cones, alluvial slopes, and a central plane. This central plane was an extension of Santa Clara Valley with an outlet through the Golden Gate gap to an ocean shoreline, which were miles from the present shore. As the melting of the continental ice sheets raised ocean levels, the valley, which is now San Francisco Bay, was progressively flooded by salt water. During this process, sandy alluvial deltas were built up upon the valley topography in shallow water, while in deeper water the fine-grained soils were deposited as mud. Eventually, the bay water level rose to sufficient height to submerge the alluvial cones at the margin of the valley, together with the intervening low ground and ravine outlets. Bay mud deposits the accumulated to a uniform level, burying the submerged ravines, cones, and deltas to vary depths depending upon the elevation of the original topography. The bay deposits can be summarized as follows: 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 10 of 58 November 12, 2007 KLEINFELDER II Bay mud; unconsolidated and soft, consisting of silty, slightly sandy clays and sandy silts often with organic inclusions. ED Alluvial sands and clays underlying the bay mud. II Lower bay clay; consolidated of similar composition as the bay mud. II Sandy soils; medium to fine, compact and angular, underlying the lower bay clay and directly overlying bedrock. II Bedrock; locally weathered and decomposed, consisting of sandstone, shale, and in places, serpentine and other intrusive rock. Available date indicates that the depth of the rock in the vicinity of Oyster Point ranges from about 10 to 100 feet. 4.2 LOCAL GEOLOGY Oyster Point is located within the historic margins of the San Francisco Bay, which is directly east of the site. According to available geological information (Bonilla, 1971), Oyster Point is underlain by artificial fill, Bay mud, and sandstone units of the Franciscan formation. Available information pertaining to historical shorelines and know fill areas (Nichols & Wright, 1971) indicates that historically the Oyster Point Marina area was developed by filling a low tideland area. The fill appears to have been placed circa 1958 at the west end of Oyster Point, and after 1958 at the east end. 4.3 FAULTING AND SEISMICITY Geologic and geomorphic structures within the San Francisco Bay Area are dominated by the San Andreas fault (SAF), a right-lateral strike-slip fault that extends from the Gulf of California in Mexico, to Cape Mendocino, on the Coast of Humboldt County in northern California. It forms a portion of the boundary between two independent tectonic plates on the surface of the earth. To the west of the SAF is the Pacific plate, which moves north relative to the North American plate, located east of the fault. In the San Francisco Bay Area, movement across this plate boundary is concentrated on the SAF; however, it is also distributed, to a lesser extent across a number of other faults that include the Hayward, Calaveras, and Concord among others. Together, these faults are referred to as the SAF system. Movement along the SAF system has been 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 11 of 58 November 12, 2007 KlEINFElDER ongoing for about the last 25 million years. The northwest trend of the faults within this fault system is largely responsible for the strong northwest structural orientation of geologic and geomorphic features in the San Francisco Bay Area. The site is situated within the San Francisco Bay Area, which is characterized by numerous active faults and moderate to high seismic activity. Based on the information provided in Hart and Bryant (1997) and CGS (2002) the site is not located within a State-designated, Earthquake Fault Rupture Hazard Zone where site-specific studies addressing the potential for surface fault rupture are required and no known active faults traverse the site. Presented below is a table showing the name, distance, direction, and magnitude of the closest faults to Oyster Point. Fault Name San Andreas - 1906 Rupture San Andreas - Peninsula San Gregorio Hayward - North Hayward - Total Hayward - South Monte Vista Calaveras (North of Calaveras Reservoir) Concord - Green Valley Healdsburg - Rodgers Creek Hayward - South East Extension Distance (km) 7.3 7.3 15.2 22.6 22.6 23.4 27.5 36.9 43.5 47.5 48.0 Direction Southwest Southwest West Northeast Northeast East Southeast Northeast Northeast North Southeast Maximum Moment Magnitude 7.9 7.0 7.3 6.9 7.1 6.9 6.5 6.8 6.9 7.0 6.5 Based on the map of known active faults (ICBO, 1998), the San Andreas fault is the closet fault and is located approximately 7.3 kilometers southwest of Oyster Point. A major seismic event on these or other nearby faults may cause substantial ground shaking at the site 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 12 of 58 November 12, 2007 KlEINFElDER 5 SITE VISIT Our site visit was performed on July 3, 2007, and consisted of observations of visual indications of settlement and other site conditions. The observations noted by our engineers included: lIiI Evidence of significant differential settlement within the roadways, particularly along Marina Boulevard. lIiI Significant differential settlement was not observed within the parking or landscape areas. lIiI Evidence of settlement of the ground surface at the base of existing pile supported structures. The Harbor Master building was observed to have settled approximately two feet from the base of the pile caps. Settlement of areas surrounding buildings was also observed at the base of the Oyster Point Yacht Club and Oyster Point Inn buildings. It is likely that the observed displacement was a result of settlement of the waste and underlying Bay Mud. lIiI Existing restroom buildings, that appear to be supported by shallow foundations such as reinforced mat slabs, show no evidence of distress due to settlement and appear to be out of level by only small amounts. lIiI Visible waste material was not observed. lIiI Evidence of displacement was observed between pile-supported fishing piers and their access ramps. lIiI Surface water drainage systems seemed to be functional, with limited shallow bonding observed in a few parking lot areas at the time of our visit. · The foundation type for the marine boat sales building is unknown, however it is a multi-level building with an adjacent retaining wall about 12 feet high. No distress was observed on either the building or the wall. In general our site visit found the site to be in relatively good condition. Buildings and other structures appeared to be functional and landscaping did not show obvious signs 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 13 of 58 November 12, 2007 KlEINFElDER of distress which can sometimes be associated with significant landfill gas leakage through a final cover. 84166 / (PLE7R4 78.doc) / jmk Copyright 2007, Kleinfelder Page 14 of 58 November 12, 2007 KlEINFElDER 6 GEOTECHNICAL FEASiBiliTY 6.1 SUBSURFACE CONDITIONS The results of our research into the site indicate that the majority of the site is underlain by landfilled solid wastes. The thickness of the landfill varies from about 4 to 42 feet, and generally increases toward the center of the site. The landfill refuse material encountered in the exploratory borings drilled previously at the site consisted of a variety of materials including wood, paper, plastic, cardboard, tin, rags, bricks, glass, and various organic debris mixed with varying amounts of soil. The bottom of the landfill is generally above elevation +10 feet (MSLD) in the western portion of the site, and as deep (in previous borings) as -20 feet in the eastern portion. A soil cap varying in thickness from about 1 to 14 feet overlies the landfill areas. The soil cap consists primarily of stiff to very stiff silty and sandy clays, and medium dense clayey sands, with occasional gravelly clay and silty sand layers. An Atterberg Limits test performed on a sample of the soil cap was indicative of a low to medium plasticity soil. The waste materials are underlain by very soft to soft clays and silty clays with organics and shells (locally known as Bay Mud). The exception to this is at the western margin of the site where the waste fill is underlain by bedrock consisting of weathered claystone, sandstone, and siltstone. The Bay Mud is underlain by bedrock in the western portion of the site or by very stiff to hard clays and dense sands under the remainder of the landfill. Geologic cross sections that show the subsurface are presented on Plate 5. Contours of Bay mud are shown on Plate 6. As shown on Plate 6, most of the site is underlain by 50 to 90 feet of Bay Mud. Groundwater elevations range from about 5 feet to 20 feet above Mean Low Low Water (MLLW), as found by a groundwater survey performed on February 7, 2000 (JTD, 2000). The higher groundwater elevations are found toward the western margin of the site where the topography is higher. The majority of the project site has a groundwater elevation from about 5 to 8 feet above MLLW. 84166/ (PLE7R478.doc) / jmk Copyright 2007. Kleinfelder Page 15 of 58 November 12, 2007 KlEINFElDER The above is a general description of the soil, waste and groundwater conditions documented within the boring logs encountered in our research. Soil and groundwater conditions can deviate from those conditions encountered at the boring locations. In addition, the subsurface conditions may have changed as a result of settlement, decomposition of waste and/or erosion, and therefore the above may not reflect the current subsurface conditions at the site. 6.2 SETTLEMENT DISCUSSION One of the major problems in designing a structure over a landfill is the significant settlements associated with the highly compressible refuse material. Significant surface settlements can be expected, and, due to the heterogeneity of the landfill refuse, the potential for differential settlements is expected to be high. The considerable settlements in a landfill mass can be attributed to three mechanisms by which these settlements occur: consolidation, compaction, filtering, and shrinkage. Consolidation of refuse material is defined as the shrinkage of saturated refuse that is subjected to a surcharge load. When subjected to a surcharge load, water is expelled from the voids within the refuse, which in turn causes settlement. This type of settlement is similar to settlement of saturated soft clayey soils and therefore can be somewhat analyzed as a soil. When the landfill material is not saturated, consolidation can occur from expelling of air, rather than water, and the crushing of the material itself, both of which are the result of loading. This type of consolidation is very difficult to model. Compaction is the settlement resulting from mechanically induced loads such as heavy equipment and traffic. This mechanism of settlement only applies to non- saturated refuse. Both consolidation and compaction of refuse are load-induced settlements. The third mechanism of settlement, known as shrinkage, is somewhat independent of the load. Shrinkage is defined as the settlement resulting from the biological conversion of refuse with organic solids into methane and carbon dioxide, or, in short, decomposition. According to Sowers (1968), there is a fourth mechanism of settlements in landfills, which is the filtering of finer materials into the void spaces between larger particles. Portions of the landfill wastes are below the site groundwater levels, and the remainder extends above the ground water levels. Therefore, consolidation settlements may be 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 16 of 58 November 12, 2007 KlEINFElDER accruing due to the expulsion of both water and air from the waste mass. The magnitude of this type of settlement is difficult to estimate. Since no new fill has been placed in over 30 years, it is speculated that much this type of settlement has already occurred. Compaction settlement is of some concern, especially in the proposed building areas. However, the magnitude of settlement due to compaction of the refuse is small compared to the magnitude of settlement due to shrinkage. Therefore, we anticipate the major portion of the settlement to be the result of shrinkage or decomposition of the refuse. The rate and magnitude of settlements resulting from the decomposition of the refuse is dependent on several factors including refuse fill thickness, composition of the refuse, and age of the refuse fill. Our review of literature indicates settlements between 10 to 30 percent of the initial refuse fill height have been experienced in landfills similar to the project site. The large variance in the magnitude of settlements is a result of the different composition of the landfills studied. According to literature reviewed, a large portion of the settlements occur within the first two years following the placement of the refuse with a relatively steady rate occurring after that for an indefinite period of time. Therefore, it is our opinion that settlements of the landfill are closer to iOta 15 percent of the initial refuse fill thickness rather than 30 percent. The thickness of the refuse fill at the subject landfill varies between 1.5 and 40 feet at the deepest portion. Considering the age of the landfill and the elapsed time since closure of the landfill, the anticipated settlements are to fall between 3 to 4 feet over the next 15 years, for the thickest portion of the landfill. Since the settlement of the landfill is time dependent and it is uncertain when the decomposition of the refuse ceases to occur, it is prudent to assume that the decomposition process occurs indefinitely. Differential settlements within the refuse portion of the site are extremely difficult to predict due to the significant variety of refuse material and its substantial thickness. Differential settlements have been measured at other landfill sites, with refuse thickness of approximately 25 to 30 feet, to be on the order of 25 percent of the total settlement. This percent was taken over a horizontal distance of 100 feet for a period of 12 years. Due to the uncertainties associated with settlement at the site and the substantial thickness of the refuse, differential settlements could easily exceed 50 percent of the total settlement over a distance of 100 feet in the next 15 years. Consideration must 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 17 of 58 November 12, 2007 KLEINFELDER also be given to differential settlement between the refuse and non-refuse portions (including pile supported structures) of the site. Since the non-refuse areas are not expected to undergo significant settlement, the differential settlement will be equal to approximately the total settlement of the refuse at the interface. Placement of additional fill at the site will result in additional settlement. The magnitude of the settlement will depend on the thickness of the fill, the lateral extent and the current thickness of the soil cap. For estimating purposes, settlements on the order of 3 to 5 inches for every foot of new fill should be anticipated. This estimate may need to be reevaluated when grading plans are finalized. Consolidation of the Bay Mud underlying the refuse in response to loads from the overlying waste and cover soils is another significant source of settlements at the site. Consolidations tests from the western portion of the landfill only were available to Kleinfelder at this time. These tests indicated that the Bay Mud has not completed consolidating in response to the overlying fill materials and is thus still settling. This is also likely the case at the more easterly sections of the landfill where Bay Mud thicknesses are greater. 6.3 SEISMIC CONSIDERATIONS The seismicity of the region surrounding the site is discussed in detail in Section 4 "Geology and Seismicity" of this report. From that discussion it is important to note that the site is in a region of high seismic activity and is expected to be subjected to major shaking during the design life of the store. As a result, structures to be constructed on the site should be designed in accordance with applicable seismic provisions contained in the 2001 California Building Code (eBC). 6.3.1 Liquefaction Soil liquefaction is a condition where saturated, granular soils undergo a substantial loss of strength and deformation due to pore pressure increase resulting from cyclic stress application induced by earthquakes. In the process, the soil acquires mobility sufficient to permit both horizontal and vertical movements if the soil mass is not confined. Soils most susceptible to liquefaction are saturated, loose, clean, uniformly 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 18 of 58 November 12, 2007 KlEINFElDER graded, and fine-grained sand deposits. If liquefaction occurs, foundations resting on or within the liquefiable layer may undergo settlements. This will result in reduction of foundation stiffness and capacities. Based on the subsurface data obtained from the previous drilled borings performed at Oyster Point (as discussed in this report), the existing landfill materials, residual soils, Bay mud, and Franciscan Complex bedrock have a low potential for liquefaction. Therefore, damage due to liquefaction at Oyster Point is considered low. It should be noted that the landfill was constructed using soil levees. These levees are reported to be constructed of Bay mud, which has low potential for liquefaction. During future investigations at the site, it is recommended that the type of material used in the existing exterior levees consists of material that has low potential for liquefaction. 6.3.2 Lateral Spreading Lateral spreading is a consequence of the liquefaction, which results lateral movement towards a slope. Because liquefaction is considered to be low at this site, lateral spreading is also considered to be low. Again, the perimeter levees should be evaluated to confirm that they consist of materials with low liquefaction potential. 6.3.3 Seismic Densification During an earthquake, there is a potential for soils to undergo densification, which could result in settlements. Typically, granular soils are the type of soils that are subject to densification during significant earthquakes. Landfill material typically behaves as a granular material. Therefore, there is potential that landfill material, if subject to a significant earthquake could result in some settlement. However, based on the longevity of the landfill, the amount of settlement due to seismic densification is not anticipated to be greater than the future settlements anticipated as a result of the consolidation of the landfill material and underlying Bay mud. Therefore, additional measures are not needed to address seismic densification. 6.3.4 Seismic Design Criteria The site is located in a seismically active region and the proposed new structure can be expected to be subjected to moderate to strong seismic shaking during its design life. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 19 of 58 November 12, 2007 KLEINFELOER Potential seismic hazards include ground shaking, localized liquefaction, ground rupture due to faulting, and seismic settlement. Of these, ground shaking is the only seismic hazard that may impact the site based on our investigation. Because this site is located in the seismically active San Francisco Bay Area, we recommend that, as a minimum, the proposed development be designed in accordance with the requirements of the latest edition of the California Building Code (CBC) for Seismic Zone 4. We recommend that a soil profile factor of SE be used with the CBC design procedure (Table 16-J). With this soil profile, it is recommended that a site response spectrum be performed. For estimating purposes, we are providing the near source seismic coefficients for acceleration and velocity, Nay Nv, Cay and Cv (CBC Tables 16-S and 16-T). The site is located approximately 7.9 km from the trace of the San Andres fault, a Type A Fault as designated by the 2001 CBC (ICBO, 1998). A summary of the seismic design parameters for this fault is presented below. Design Fault San Andres fault Fault Type A Seismic Zone 4 (z = 0.4) Soil Profile Factor (Table 16-J) SE Near-Source Distance 7.9 km Na (Table 16-S) 1.08 Nv (Table 16- T) 1.37 Ca (Table 16-Q) 0.44 x (Na) 0.39 Cv (Table 16-R) 0.64 x (Nv) 1.31 6.4 FOUNDATION SYSTEMS 6.4.1 Pile Foundations 6.4.1.1 General Based on the results of our geotechnical evaluation, it is our opinion that a feasible foundation alternative to support the convention center and hotel structures is a system of precast, prestressed concrete piles driven approximately 30 feet into the stiff to hard 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 20 of 58 November 12, 2007 KlEINFElDER clays, dense sands or weathered bedrock underlying the landfill and Bay Mud (where encountered). Both the structural loads and building floor slabs should be supported on piles. It is recommended that, not to the exclusion of other pile sizes, 12- or 14-inch square precast prestressed concrete piles be used. Steel piles are not recommended due to the corrosive nature of the landfill material. However, an alternative pile system is to drive closed end pipe piles, with the interior of the pile filled with concrete after driving. Whereas, this alternative is generally more expensive than precast concrete piles, due to the variability in the lengths of the piles due to variability in the depth and hardness of the underlying clays, sands or bedrock, this alternative may be feasible. It is recommended that the piles be predrilled through the fill and landfill materials, if possible, to protect the piles from damage due to unknown materials, to reduce pushing refuse material deeper, as well as to mitigate pile alignment problems. The drill should only loosen and break up obstructions in-place which may cause damage to the pile. Due to environmental concerns, the auger should not be pulled out with refuse. The diameter of the predrilled hole should not exceed the pile width/diameter. Piles placed into oversized predrilled holes should be grouted to regain required lateral capacities. The landfill and underlying Bay mud are still undergoing settlement as discussed in Section 6.2 "Settlement Discussion". Since the piles will extend through the landfill and Bay mud into the low compressible clays, sands and bedrock beneath the Bay mud, the settlement of the landfill and Bay mud will exert a downward load (typically called "downdrag") on the piles. As a result, either the capacity of the pile will need to be reduced by this downdrag load, or that the impact of the downdrag load on the pile is reduced. For the anticipated geologic cross-section at Oyster Point the amount of downdrag could reduce the capacity of the pile by 65 to 80 percent of the design allowable capacity of the pile. For a 14 inch pre-cast, pre-stressed pile driven to about 150 feet below the current ground surface, the design load would typically be about 250 kips (1 kip = 1,000 pounds). The downdrag load would then reduce this capacity. Another option is to coat the pile with bitumen. This is an asphalt derived material that would significantly reduce the downdrag loading on the pile. Lateral loads imposed on the building foundations can be resisted by a combination of the resistance of the pile-soil system to deflect, and the passive resistance acting against the face of pile caps and grade beams. The strength of the material in the upper 15 feet of the site typically dictates the resistance capability of the pile-soil 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 21 of 58 November 12, 2007 KlEINFElOER system. For Oyster Point, the capacity of the resistance of the pile-soil system to lateral loads would be typical for most projects developed around the fringe of the San Francisco Bay. 6.4.1.2 Indicator Piles Prior to specifying the lengths of the production piles, it is advisable to drive indicator piles at the structure sites in order to observe the driving characteristic of the piles and the ability of the driving equipment when a driven pile is used. The driving criteria and pile length of production piles will also be estimated from the information obtained from driving of the indicator piles. The contractor should use the same equipment to drive both the indicator and production piles. Indicator pile lengths and locations should be selected by the Geotechnical Engineer, in conjunction with the Structural Engineer and Contractor after the foundation plan has been finalized. The indicator pile program will serve to establish the following: · Estimates of production pile lengths; · Driveability of production piles; · Performance of pile driving equipment; · Variation in driving resistance relative to depth and location of piles. 6.4. 1.3 Production Piles Production piles should be installed with the same equipment used for the indicator piles and under the observation of the geotechnical engineer. The need for predrilling should be assessed during the indicator pile program. If voids or gaps are found around the installed piles, those voids or gaps should be backfilled with cement grout. Because of the variability of the depth to and hardness of the clays, sands and bedrock, even with a pile indicator program, it is anticipated that many piles will not be driven to design "top of pile" elevation, and will result in significant cutoffs, both in number and in length. Including additional reinforcing steel in the upper portions of the pile should be avoided, or significantly lengthened, to address the anticipated cutoffs. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 22 of 58 November 12, 2007 KlEINFElOER 6.4.1.4 Settlements Future settlements of loaded piles will be due to the elastic compression of the pile and the subgrade response of the clays, sands and weathered bedrock which supports the piles. It is estimated that the total settlement of the pile supported foundations will be on the order of Y2 inch to 1-inch, with differential settlements between columns not exceeding about one-half that amount. The majority of these settlements should occur during construction of the buildings as the loads are applied. 6.4.2 Shallow Foundations Although we do not anticipate any lightly loaded single story buildings to be constructed, we anticipate that the building loads for any such buildings may be feasibly supported on reinforced mat slab foundations similar to those that support the existing restroom buildings at the project site. 6.5 GROUND IMPROVEMENTS Several techniques are sometimes used at landfills in an effort to reduce settlements. These may include dynamic deep compaction or preloading with soil fills. Although these techniques can reduce settlements in waste materials, they do not eliminate them, as they do not prevent decomposition. These techniques would not likely improve the Bay Mud properties significantly in much of the site. Accordingly, we do not feel they are particularly feasible at Oyster Point. 6.5.1 Earthwork Grading, excavation, and earthwork at the site will generally consist of stripping and clearing the site of surface vegetation and debris, preparation of the subgrades for concrete slabs, exterior flatwork and pavements, and excavations for pile caps and underground utilities. The amount of grading is unknown at this time, but it is anticipated that cuts and fills will be minimal in order to avoid penetrating the soil cap over the existing landfill, and to reduce the amount of long term settlement, respectively. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 23 of 58 November 12, 2007 KlEINFElDER Areas to be graded should be stripped of existing surface vegetation, organic topsoil, and debris. An average stripping depth of a couple of inches is estimated for most of the site. These materials should not be reused for engineered fill and should be removed from the site, or used in landscape areas, as appropriate. Due to the generally heterogeneous nature of most landfills, it is anticipated that there will a large amount of differential settlement within the soil cap of the site. This differential settlement can disrupt drainage patterns and cause damage to pavements and soil supported structures. Although it is our opinion that there is no feasible way to prevent this differential settlement from occurring, we feel that it can be reduced by placing a geogrid under the baserock underneath the pavements and exterior flatwork. Although the geogrid will not prevent differential settlement below these areas, it will greatly increase the ability of the subgrade soil to bridge over minor deficiencies In subgrade support. In addition to the placement of geogrid, the upper 12 inches of subgrade soils under all pavements and exterior slabs-on-grade areas will likely require scarification, moisture conditioning and recompaction. Grading operations during the wet season or in areas where the soils are saturated may require provisions for drying of soil prior to compaction. If the project necessitates fill placement and compaction in wet conditions, we could provide alternatives for drying the soil. Conversely, additional moisture may be required during the dry months. Water trucks should be available in sufficient number to provide adequate water during compaction. 6.5.2 Pavements Pavements for this project are anticipated to consist of asphalt concrete roads, access driveways and parking areas. We assume vehicle loading for this project will be variable and consist of passenger vehicles as well as occasional trucks. Parking areas should be sloped and drainage gradients maintained to carry all surface water off the site. Surface water ponding should not be allowed anywhere on the site during or after construction. Due to the expected differential settlements, it is 84166 / (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 24 of 58 November 12, 2007 KlEINFElDER anticipated that this will require a continuous maintenance program to repair low areas that inhibit drainage. Where concrete curbs are used to isolate landscaping in or adjacent to the pavement areas, we recommend the curbs extend a minimum of 2 inches below the baserock and into the subgrade to provide a barrier against drying of, or migration of landscape water, into the pavement section. It was our observation during our site reconnaissance that the existing roadways experienced significant differential settlement. As previously described above, we recommend that a geogrid stabilization fabric be used beneath the baserock to lessen the effects of settlement on future roadways. In addition, we recommend that all pavements conform to the following criteria: e All trench backfills, including utility and sprinkler lines, should be properly placed and adequately compacted to provide a stable subgrade. e An adequate drainage system should be provided to prevent surface water or subsurface seepage from saturating the subgrade soil. e The aggregate base and asphalt concrete materials should conform to ASTM test procedures and work should be performed in accordance with Caltrans Standard Specifications, latest edition. 6.5.3 Site Drainage Proper site drainage is important for the long-term performance of the planned structures. The site should be graded at a minimum of 3 percent promote surface water runoff and prevent ponding. In addition, all roof gutters should be connected directly into the storm drainage system. As previously discussed, differential settlement is expected to disrupt drainage patterns over time. We anticipate long term maintenance will be required to maintain adequate drainage. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 25 of 58 November 12, 2007 KlEINFELDER 6.6 LANDFILL DESIGN IMPACTS As stated in the "Settlements" section of this report, significant settlements are expected to occur in the landfill waste material and Bay Mud during the life of the project. As a result of these settlements there will be significant differential settlements between the pile supported structures and the surrounding structures and ground surface supported on the landfill. In order to maintain the integrity and aesthetics of the structures, walkways, and utilities that cross the interface between the settling land and the buildings, special considerations will need to be incorporated into the design and maintenance plans prepared for these components of the project. Structures not supported on piles should not be structurally tied into pile supported buildings, except as noted below, and should be designed to allow free vertical movement between the structure and the building. If maintaining the relative vertical position between structures is necessary, both of the structures should be supported on piles and structurally tied together. We recommend the use of articulated ramps on walkways and building entrances at the interface between the pile and soil supported areas. Articulated ramps will provide a smooth walkway over moderate differential settlements with some amount of maintenance. As the magnitude of the differential settlement increases, however, these ramps may need to be rebuilt or realigned to account for the larger elevation differential. Similar ramps should also be used on driveways leading into pile supported parking lots. It is recommended that wall skirts that extend below the ground surface be constructed around the perimeter of the proposed buildings. These skirts should extend to a depth of at least 5 feet. The purpose of the skirt is to hide the void which will develop beneath the buildings due to the ground settlement. Utility lines leading into the proposed buildings will also need to be designed to accommodate the anticipated differential settlement. This is discussed below in the "Utilities" section of this report. 84166 I (PLE7R478.doc) I jmk Copyright 2007. Kleinfelder Page 26 of 58 November 12, 2007 KlEINFElDER 6.6.2 Utilities 6.6.2.1 Excavation and Backfill Excavation for pile caps, grade beams, curtain walls, and utility trenches can be readily made with either a backhoe or trencher. It is expected that excavations in the soil cap material less than 4 feet in height will stand near vertical for a period of several days with some minor sloughing being expected from some of the cleaner sand deposits. Where excavations are extended deeper than about 4 feet, the excavation may become unstable and should be evaluated to monitor stability prior to personnel entering the trenches. Shoring or sloping of any deep trench wall may be necessary to protect workmen and to provide stability. All trenches should conform to the current CAL-OSHA requirements for work safety. Excavations extending into the refuse fill are expected to encounter potentially hazardous conditions including poisonous and explosive gases. Special precautions should be taken to monitor the safety conditions and to provide for the safety of workers in the area. Additionally, if excavations encounter water, this water may have to undergo specialized handling, treatment and/or disposal if it is contaminated. Special care should be taken in the control of utility trench backfilling in the pavement areas. Poor compaction may cause excessive settlements resulting in damage to the pavement structural section. 6.6.2.2 Building Connections Underground utilities should be located, designed, and constructed to reduce distress due to differential settlement. Consideration may be given to locating the utilities in a common trench where located in landfill areas to reduce the amount of special mitigation measures. It is expected that, even with special design to mitigate the expected differential settlement, extra maintenance and repair will be necessary on the utility lines located in the landfill cap. If possible, the utilities should be constructed in the soil landfill cap to avoid contact of the utility lines and construction workers with the refuse material. If construction of utilities in the refuse material is necessary, proper design and construction precautions 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 27 of 58 November 12, 2007 KlEINFElDER should be taken to protect the system and the workers from the corrosive and hazardous conditions of the refuse. In addition, a minimum of 6 inches in thickness of granular fill should be placed beneath the utility lines to provide a proper bed for the pipes over the refuse. Following installation of utilities either in the refuse or in the overlying cap, methane gas may collect within the trench backfill. To help mitigate this, either a system to disperse methane should be installed in the trenches or the trenches should be sealed. Typical types of sealing procedures include providing a low permeability clay cover of 1 foot over the top of the pipe, or the utility trench be wrapped with a relatively impervious geomembrane. Underground manholes should be shielded from methane intrusion by placement of a membrane around the outside of the structure. To reduce gas migration off-site within the utility trenches, all trenches crossing the transition zone between the landfill and non-landfill portions of the property should be sealed with a clay plug surrounding the pipe or other approved methods. In addition, plugs should also be provided at the perimeters of buildings to reduce migration of gas through the utility trenches to beneath the building. It is recommended that utility lines be constructed of flexible pipe such as welded polyethylene to accommodate differential settlement within the refuse material and landfill cap. At the border of the landfill, where differential settlements between the refuse material and soil are expected to be large, the utility lines should be designed to allow for rotation. As with buried utilities on a conventional site, proper bedding and backfilling should be completed. On a landfill site these aspects become even more important as a result of the generally higher levels of settlement that occur. It is also prudent to increase the flow gradient in sewers and storm drains so that differential settlements will not disrupt the flow. An alternative would be to provide a pumping system that does not rely on gravitational flow. It is anticipated that the most crucial sections of the utility lines will occur at the interface between the soil supported utility line and the pile supported buildings. At this interface differential settlements of several are not unlikely. Vaulted systems should be designed and maintained at this interface that provides a flexible and/or expandable connection to the proposed buildings. In addition the utility lines beneath buildings should be suspended from hangers fastened to structural floor slabs. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 28 of 58 November 12, 2007 KlEINFElDER · Erosion Resistant Laver: A compacted soil layer consisting of not less than one foot of soil, containing no refuse materials, will be placed on top of the low- hydraulic-conductivity layer. The actual thickness of the erosion resistant layer varies in accordance with final subgrades. The cover system to be used in the landscape and paved areas will be the same as the structure areas with the exception that the erosion resistant layer will likely be increased in thickness. The variation in thickness is dependent upon the intended use. The thickness of the temporary erosion resistant layer during construction in landscaped and paved areas should be not less than 2 feet above the low-hydraulic-conductivity layer to protect this layer prior to final grading and planting or paving. The final thickness of the erosion resistant layer in landscaped areas will vary in accordance with the landscape plan, but should not be less than 2 feet. The erosion- resistant layer section above the low-hydraulic-conductivity layer and beneath paved areas should not be less than 18 inches of compacted soil. 7.3.2 Modification of Current Cover According to previous investigations performed at the site, the cap varied in thickness from 1 foot in the center of the site to 14 feet at locations along the perimeter. Kleinfelder has not found evidence documenting changes in the cover thickness subsequent these investigations. Development of the site will require bringing the landfill cover into compliance with regulatory requirements for closure. 7.3.3 Landscaping and Irrigation Aspects Landscaping of the site should be selected to stabilize the soil, preventing erosion, and to reduce the need for extensive irrigation. Excessive water could infiltrate the landfill cap and produce leachate which would require treatment. To prevent this, low-water vegetation should be selected to reduce irrigation water. In addition the thickness of the erosion resistant layer should be varied as follows: · A 24-inch vegetative soil layer in landscaped areas featuring grass and shallow rooted scrubs, and 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 34 of 58 November 12, 2007 KlEINFElDER · A 4-foot soil layer in areas intended for small trees and larger scrubs with deeper root structures. If larger trees are selected for planting the depth of the erosion resistant layer should be increased to prevent intrusion of the tree roots into the lower layers of the cover. 7.4 LEACHATE MANAGEMENT SYSTEMS 7.4.1 Leachate Monitoring As discussed above, semi-annual monitoring of groundwater and leachate currently occurs on site per the RWQCB order No. 00-046 and the JTD. Ten of the 18 monitoring wells on site were installed and screened within the waste on site. Eight of these wells were sampled and analyzed for benzene, ethylbenzene, xylenes, chlorobenzene and naphthalene on December 1, 2006. Results were compared to MACLs, as defined in Section 7.1. Well GW-12a, located near the west end of the site adjacent to Marina Boulevard, had benzene detected at a concentration higher than the MACL. Well GW-10a, located near the center of the site, had naphthalene detected at a concentration higher than the MACL. Well 3a, located near the east end of the site, had ethyl benzene, xylenes, and chlorobenzene detected at concentrations higher than their respective MACLs. The remaining five wells were above the LOD for at least one of the analyzed constituents, but were below the MACLs. As discussed in Section 7.1.1.1, chemicals of concern were not detected in perimeter groundwater wells at concentrations at or above the MACLs. This suggests that elevated chemical concentrations are generally confined to the refuse containing areas of the landfill. 7.4.2 Existing Systems The landfill is unlined and lacks a leachate collection and removal system. Leachate is currently contained by Bay Mud underlying the site, various trenches and the final 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 35 of 58 November 12, 2007 KLEINFELDER cover. Routine inspections of the cover to check for structural integrity and for leachate seeps are included in post-closure monitoring. 7.4.3 Need for Modifications There is no current need to modify the treatment of leachate on site, however measures should be included in the design to limit increased percolation of rain fall, runoff and irrigation water into the waste areas. These measures should include directing all roof runoff directly to storm drains, modification of the existing cover to bring it into compliance with regulatory requirements for closure, and reduction of the need for irrigation water usage. 7.5 LANDFILL GAS SYSTEMS Section 21160 of Title 27 of the CCR requires that closed landfills implement and maintain landfill gas control. In addition, the proposed post-closure land use plan shall be submitted for approval to the California Integrated Waste Management Board (CIWMB), Regional Water Quality Control Board (RWQCB), BAAQMD, and County of San Mateo Division of Environmental Health. We recommend that a preliminary plan be developed and submitted as early as possible for their conceptual approval. According to Kleinfelder's 1999 Environmental Investigation Survey Report, methane and other landfill gases are present at levels above the LEL throughout the landfill. Section 21160 of Title 27 of the CCR requires that closed landfills implement and maintain landfill gas control. In addition, the proposed post-closure land use plan, describing the new development and modifications to the landfill shall be submitted for approval to the California Integrated Waste Management Board (CIWMB), Regional Water Quality Control Board (RWQCB), BAAQMD, and County of San Mateo Division of Environmental Health. We recommend that a preliminary plan be developed and submitted as early as possible for their conceptual approval. This document will be a supplement to the information currently presented in the JTD. In addition to methane, other landfill gases that could present a potential health risk have been identified. One significant compound identified in several gas probes was benzene. It is a known carcinogen and does post a health risk, if not appropriately 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 36 of 58 November 12, 2007 KlEINFElDER mitigated. The highest concentration of benzene identified was in the area of the liquid waste sump at the eastern edge of the site. VVe recommend that construction in this area be minimized to reduce the potential for explosive and toxic gases and reduce cost for excavating and disposing of hazardous materials. We also recommend that several environmental borings be performed to evaluate the limits of the liquid waste sump and identify cost impacts on the development. In addition, LFG venting trenches have been recently installed along Gull Drive and Oyster Point Boulevard. Review of the installation details and the post-installation soil vapor sampling events should be reviewed as they become available. The existing landfill presently does not have a landfill gas recovery system. It should be noted that Terra Engineers has recently installed two passive recovery trenches and additional soil vapor monitoring wells along Gull Drive and along Oyster Point Boulevard. Mr. Bob Kirby of Terra Engineers reported that the system along Gull Drive has contributed to a decrease in the detected levels of methane in soil gas to below 50/0 by volume, which is the lower explosive limit (LEL) for methane. Mr. Kirby also indicated that the trench installed in September along Oyster Point Boulevard is currently passively vented. Weekly monitoring near this trench indicates that methane levels are still above the 50/0 LEL, although the levels are decreasing. If the levels stabilize above 50/0 it is planned to add an air turbine to the top of the vent pipe. If this does not decrease methane levels to below 50/0 then a blower will be added to the system to actively withdraw soil gas. Proposed development structures will be equipped with methane detection systems and structure venting systems. A general design for high intensity development is presented below. 7.5.1 Shielding and Venting A landfill gas venting system should be placed under the bottom slabs of each structure to collect and vent the build up of gases diffusing through the landfill cap. The landfill gas venting system typically consists of the following elements from the bottom up: .. Non-woven geotextile fabric; .. 12 inches minimum of washed crushed gravel free of fines, with perforated flexible polyethylene or rigid PVC pipe; 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 37 of 58 November 12, 2007 KlEINFELDER . Non-woven geotextile fabric; · Reinforced concrete slab (first floor); · 50-mil HOPE geosynthetic membrane or spray-on membrane such as Liquid Boot; · Non-woven geotextile fabric; and · Thin protective concrete topping slab. Potential migration of LFG into the building space should be mitigated by the collection and venting system, and secondly by the HOPE membrane. Subsurface landfill gasses should be vented by a network of perforated piping placed beneath the building slabs within the continuous gravel layer. The exhaust gases should be manifolded to a series of riser piping that is to be vented above structure roofs. Vent points should be located away from building air intake points. Monitoring should be performed in both the subsurface space (below slab) and interior first floor spacer. If monitoring indicates a buildup of LFG, an electrical blower should be installed to extract LFG below the slab. The LFG riser discharge at the roof should have a pre-installed electrical service booth to allow easy system retrofitting with an electrical blower. 7.5.2 Monitoring Methane sensors should be installed in structures in the subsurface (for monitoring only) and first floor levels. Subsurface monitors are typically placed at approximately one per 10,000 square feet of floor area. The subsurface monitors will be used to evaluate the build of gases and efficiency of operation. Sensors are connected to controllers to allow the activation of blowers to exhaust the gases if the passive ventilation is not sufficient. The first floor sensors will be installed in each room with a minimum coverage of one per 5,000 square feet. Sensors will be connected to a centralized alarm system similar to the fire system for monitoring and control. Monitoring, calibration, maintenance and response protocols should be provided in the post-closure maintenance plan. Typical action levels are set as follows: 84166 I (PLE7R478.doc) I jmk Copyright 2007, Kleinfelder Page 38 of 58 November 12, 2007 KLEINFELDER MONITOR ACTION LEVEL (%LEL 1) Caution 20 Warning 30 Alarm 40 Caution 10 W arning2 202 Alarm2 402 Subsurface (secondary level) First Floor (primary level) Note: 1. LEL - Lower Explosive Limit 2. Warning and alarm levels established by SMCEHA The LEL is defined for methane gas as 5 percent methane by volume in air. In accordance with CCR Title 27 Division 2, Sections 20919.5(a)(1) and 20921 (a)(1), the allowable level of methane gas in site structures is 25 percent of the LEL, or 1.25 percent methane by volume in air. The proposed LFG monitoring system provides redundancies and early warnings to prevent gas infiltration. Only the warning and alarm signals from the primary monitoring system should activate the City fire department to respond. The other signals emanating from the secondary monitoring system are for in-house system monitoring performance. 7.5.3 Permitting The BAAQMD does not currently require permitting for passive soil vapor intrusion systems, which includes the LFG system as described above. However permits are required for active systems, which are defined, in part, as systems with an attached motorized blower. In the event that monitoring of emissions indicates the need for addition of a blower to the system, a permit for the retrofit activities would be required at that time. In addition, permitting will be required if the emissions of individual contaminants exceeds the trigger levels as defined in BAAQMD regulation 2 rule 5. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 39 of 58 November 12, 2007 KlEINFElDER 7.6 CONSTRUCTION CONSIDERATIONS 7.6.1 Worker Safety Prior to construction a site specific health and safety plan should be developed to protect worker safety during construction activities. At a minimum it should include information related to the health effects of the chemicals of concern at the site, directions and contact information for at least one urgent care center, plans for personal and perimeter air monitoring and contingency plans for respiratory protection and other forms of personal protective equipment based on detected levels of chemicals of concern. 7.6.2 Excavations Excavation into the landfill in some portions of the site is anticipated to allow construction of both the final cap, as described in Section 7.3, and the site structures. Excavation of existing landfill cover and refuse will be required to allow construction of the approved cap beneath areas requiring deeper building components, such as pile caps. Two options are available for landfill waste disposal: off-site at an approved landfill facility, or on-site as part of the building fill material. Off-site disposal will require pre- characterization of the refuse for acceptance at an approved waste disposal facility. Waste manifests will need to be prepared to document transportation and disposal. On-site disposal will require proper placement, compaction, and capping of the refuse material. In either case, segregation of Class 2 and Class 3 from Class 1 material for disposal purposes should be performed on-site to the extent possible. No Class 1 material can be relocated on-site. During excavation the waste should be visually inspected for indications of hazardous materials such as liquids, sludges, chemical containers including paint cans or other visible indications of chemical wastes. Waste with visible evidence of potentially hazardous chemicals should be segregated for further characterization. Disposal facilities should be identified prior to excavation activities and criteria should be 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 40 of 58 November 12, 2007 KLEINFELDER established for pre-acceptance of waste to facilitate timely removal of the waste. A discussion of waste removal procedures is included in Section 7.2. Although, it is desirable to keep excavations to a shallow depth to reduce impacts on the existing landfill cap and the amount of waste excavated, if excavations should encounter water including landfill leachate, these liquids will likely have to receive special handling, treatment and/or disposal. Typically this includes on-site tankage to hold pumped liquids prior to testing of the chemical quality. Some treatment may also be necessary prior to discharge of the liquids either to a sanitary sewer, if allowed or to other suitable treatment or disposal facility. Because most of the excavations should be above the level of groundwater or leachate, we have not included these costs on our cost estimates included herein. 7.6.2. 1 Permitting BAAQMD Regulation 8 Rule 34 section 118 documents a limited exemption for construction activities at landfill sites. This section specifies that when the construction activities are related to "installing, expanding, replacing, or repairing components of the landfill gas, leachate, or gas condensate collection and removal systems." However according to Mr. Robert Cave of the Air Toxics Department, excavations for the purposes of grading and construction will be regulated under this section. As such it will be necessary to provide BAAQMD with construction plans and other documentation as detailed under this regulation for the purposes of obtaining a letter of exemption from BAAQMD. 7.7 OPERATIONS AND MAINTENANCE Operation and maintenance activities at the site during the post-closure maintenance period consist of inspections and observations of site features to protect the landfill cap, prevent utility damage, and maintain the landfill gas barrier and venting systems. The primary activities will be with respect to erosion, drainage facilities, and ongoing landfill settlement. Additionally, the landfill gas (LFG) monitoring system will require calibration and inspection approximately every 3 months (quarterly). A description of the components requiring inspection and the observations required is described below. 84166/ (PLE7R478.doc) / jmk Copyright 2007. Kleinfelder Page 41 of 58 November 12, 2007 KLEINFELDER 7.7.1 Erosion All landscaped areas shall be visually inspected for excessive erosion once during the dry season and monthly during the wet season. Inspections shall be documented and records shall be kept of such inspections. Inspection records shall include recommendations of any necessary repairs. 7.7.2 Drainage All site drainage features (downspouts, catch basins, storm drains, etc.) shall be visually inspected for proper drainage once during the dry season and monthly during the wet season. Inspections shall be documented and records shall be kept of such inspections. Inspection records shall include recommendations of any necessary repairs. 7.7.3 Settlement The entire site shall be inspected biannually for signs of settlement. I nspections shall be documented and records shall be kept of such inspections. Inspection records shall include recommendations of any necessary repairs. 7.7.4 Landfill Gas Monitoring System Periodic maintenance of the LFG monitoring system is necessary for proper operation. The LFG monitoring system consists of a control panel(s) and combustible gas (Le. methane) transmitters (sensors). The sensors are located in various locations throughout the structures. Some of the sensors are installed to monitor the subsurface concentration of LFG and the remaining sensors are installed within structures to monitor the aboveground concentration of LFG. 7.7.4. 1 Sensor Calibration Calibration shall occur at intervals according to manufacturer recommendations, or at a minimum of every 90 days. The calibration essentially consists of applying gases of 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 42 of 58 November 12, 2007 KLEINFELDER known concentrations, noting the systems response and adjusting the sensors accordingly. 7. 7.4.2 Sensor Head Replacement Typical sensor head life is 1 to 3 years depending upon the environment in which the sensor is placed and the concentration of combustible gas exposed to the sensor. The sensor should be replaced when the sensor can not be successfully calibrated or is operating improperly. The sensor head shall be replaced in accordance with the manufacturer's recommendations. The replacement period for the sensors maybe reduced due to the presence of other volatile organic compounds in the LFG. 7.7.4.3 Battery Replacement If the control panel is equipped with a battery for memory retention, the battery shall be replaced as per the manufacturer's recommendation. 7.7.4.4 Generallnspection During the calibration event, the following additional items will be performed: ., The control panel and sensors shall be visually inspected to determine if dust is building up. If necessary the dust should be removed as per manufacturer's recommendations; ., Wiring that can be visually inspected shall be checked for damage and or corrosion; ., The sensors shall be inspected periodically for moisture or water accumulation; ., The subsurface enclosures shall be inspected for proper seal around the top portion and on the seal of the impermeable membrane; and ., The portion of the impermeable membrane that is visible from the inside of the subsurface enclosure shall be inspected for any voids, tears or abnormalities. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 43 of 58 November 12, 2007 KlEINFElDER If any of the above mentioned items are in need of repair, the repairs shall be performed in accordance with the manufacturer's recommendations. 7.7.5 Reporting A report shall be prepared documenting calibration and inspection activities. The report shall include the details of all necessary repairs required or performed. These reports shall be maintained at the landfill during the entire post-closure period. 7.8 REGULATORY COORDINATION Successful landfill post-closure development projects are aided by early and continuing communication with regulatory agencies. It is recommended to meet with and provide written submittals to agencies from the early conceptual design and feasibility stage through the permitting state, and on through construction documents and actual construction. Agency staffs appreciate open communication and the potential to provide input along the way as a project develops. This mode also facilitates approval of permitting and construction documents as agency staffs are familiar with projects and their features. Environmental consultants for the project should be selected who are familiar with the specifics of the review process and the level of detail needed for submittals. They should also work closely with City staff to communicate effectively with the regulatory agencies and prepare clear and concise submittals for agency review. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 44 of 58 November 12, 2007 KlEINFElDER 8 ESTIMATED COSTS 8.1 SUMMARY The information used to develop this cost estimate is based on a conceptual model consisting of a high density conference center/hotel option as shown on Plate 2 High Intensity Development Concept Plan. This type of estimate is sometimes referred to as a "conceptual" or "preliminary" estimate. Such estimates are usually made without detailed engineering data, examples of which include estimates from cost capacity curves, scaling of cost information or quotes, ratio estimates based on purchased equipment, or other baselines. These types of estimates are normally considered to be +50/-30 percent accurate. The high intensity plan includes buildings as follows: II A 9-story hotel with a footprint of about 18,000 square feet II A 17 -story hotel with a footprint of about 18,000 square feet III A single high story convention center with a footprint of about 150,000 square feet III A two-level parking structure with a footprint of about 42,500 square feet. Therefore, our estimate is based on about 240,000 square feet of building footprint. The purpose of our cost estimate evaluation was to compare the increase costs to develop the proposed concept at Oyster Point, as compared to a 'Traditional Solid Ground" site. In performing this evaluation, there are two components that impact the increase in cost to develop at Oyster Point. One is the landfill, and the other is the Bay mud beneath the landfill. There are many similar types of developments in the San Francisco Bay Area that are underlain by just Bay mud. Therefore, we have provided a cost estimate difference for both a Bay mud condition and a 'Traditional Solid Ground" site. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 45 of 58 November 12, 2007 KlEINFELDER A "Traditional Solid Ground" site would typically be located away from the bay, and the development would be constructed on a shallow foundation system consisting of isolated and continuous footings that would be about 4 to 5 feet thick bearing on strong soil or rock. There would be only minor concerns about settlement of the floor slab and site improvements. A Bay mud site would require the use of a deep foundation system (such as driven piles) to support the planned buildings. The system would extend below the existing Bay mud at the site. For our comparison, we have assumed that the thickness of the Bay mud would be equivalent to that encountered at Oyster Point; therefore the same site but without the landfill. There would be some site settlement, which would depend on the amount of fill, but not to the extent as the combination of Bay mud and landfill material at Oyster Point would produce. Environmental issues where not included in the cost for the "Traditional Solid Ground" and Bay mud sites. In summary, the increased environmental and geotechnical cost of development at Oyster Point, as compared to a "Traditional Solid Ground" site is estimated to be about $33,000,000. This increased cost is equivalent to about a 15 percent increase in costs as compared to a "Traditional Solid Ground" site. For comparison to another site underlain by Bay mud only (no landfill), the increase in geotechnical and environmental costs for developing at Oyster Point is estimated to be about $8,500,000 more. This increased cost is equivalent to about a 4 percent increase as compared to a Bay mud site. These numbers can be summarized as follows: Traditional site -> Oyster Point = $33,000,000 more (or about 150/0 increase) Bay mud site -> Oyster Point = $8,500,000 more (or about 40/0 increase) The table below presents a summary of the difference between the three site conditions for the various subgroups that include Geotechnical Construction Only, Environmental Construction Only, Geotechnical Related Operations per year and the Environmental Related Operations per year. A more detailed discussion of the basis of this cost estimated is presented following the table below. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 46 of 58 November 12, 2007 KLEINFELDER TABLE OF ESTIMATED ADDITIONAL COSTS OYSTER POINT DEVELOPMENT Total Cost Increase Increased Cost Increased Cost Estimate between Between Traditional Between Traditional Tradition Solid Solid Ground and Solid Ground and Ground and Oyster Area of Impact Bav Mud Site Landfill Site Point Geotechnical $24,000,000 $29,000,000 $29,000,000 Construction Only Environmental None anticipate $3,200,000 to $3,200,000 to Construction depending on $3,500,000 - Increase $3,500,000 - Only previous use of a bout 1 .50/0 of total I ncrease of about construction costs 1.501<> of total construction costs Geotechnical Estimated at $2,500 Estimate at $7,500 Estimated at $10,000 Related per year per year per year Operations per year Environmental None anticipated $20,000 to $30,000 $20,000 to $30,000 Related depending on per year per year Operations per previous use year In summary, the increased cost of development at Oyster Point including both geotechnical and environmental related construction and operations costs, as compared to a Traditional Solid Ground site is estimated to be about $33,000,000. This increased cost is equivalent to about a 15 percent increase in costs as compared to a Traditional Solid Ground site. For comparison to another site underlain by Bay mud only (no landfill), the increase in cost for developing at Oyster Point is estimated to be about $8,500,000 more as compared to a Bay mud site. This increased cost is equivalent to about a 4 percent increase as compared to a Bay mud site. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfetder Page 47 of 58 November 12, 2007 KlEINFElDER The above percentages are based on an overall cost of the development to be approximately $200 million. The basis of this construction cost estimate for the buildings and grading is as follows: ~ Hotels and convention center at $300 per square foot for construction costs; there is an estimated square footage of 620,000 square feet ~ Parking structure at $65 per square foot for construction costs; there is an estimate square footage of 85,000 square feet ~ Site grading at $3.50 per square foot; there is an estimate of 1.5 square foot of development 8.2 GEOTECHNICAL COST ESTIMATES 8.2.1 Geotechnical Cost Estimate Summary Additional costs for developing Bay mud and landfill sites based upon geotechnical concerns, as compared to a traditional solid ground site are generally related to the use of a deep foundation system, whether the floor slab needs to be structural supported, and whether special requirements are needed in the site work. In addition, because of the differential settlement of the site adjacent to the planned structures, there will also be additional maintenance costs. These costs are estimated as follows: ~ Pile Foundation $5,000,000 ~ Structural Slab $19,000,000 ~ Landfill Fill Related Improvements $5,000,000 ~ Monitoring $10,000 per year We have provided a discussion of the basis of these estimated costs and a more detail description of the involvement that will be required in the following subsections of this report. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 48 of 58 November 12, 2007 KLEINFELDER 8.2.2 Pile Foundations Typical costs for a 12 to 14-inch driven pile is between $40 and $60 per foot of depth. Assuming an embedment depth into the bedrock of about 30 feet, the assumed pile length will be about 150 feet. Therefore, for every 190 kips (1 kip = 1 ,000 pounds) of load, the cost for a pile foundation will be $6,000 to $9,000. The total weight of the structures is estimated to be 150 pounds per square foot of floor space. There is about 700,000 square feet of floor. Therefore the total weight of the structures is 105 million pounds. That would require about 550 piles. Based on using 14-inch pre-cast prestressed concrete piles, the estimated cost is about $5 million. Slab Because the buildings and parking structure will be supported on driven piles and because the anticipated settlement of the site, the floor slabs for the buildings will also need to be pile supported. The ground level for the parking structure can consist of asphalt paving that can settle with the underlying soils. However, for this cost estimate, we have assumed that the ground level slab for the parking structure will be supported on pile. To support the floor slabs on piles, the floor slabs will need to be thickened in order to span between piles. The increase cost of the floor slabs is about $0.50 per square foot per inch of thickening. We anticipate a thicken floor slab of 9 inches, as compared to a typical slab of 5 inches in thickness. There is about 240,000 square feet of slab. At 4 additional inches, the increase in cost would be about $480,000. To support the slabs, it is estimated that piles would be required at about 8 feet on center. With 240,000 square feet of slab, the number of piles would need to be 3,750. Subtracting the piles needed to support the building loads, the additional piles need to support the floor slab would be 3,200. The additional estimated cost for these piles would be about $19 million (based on 12-inch piles). The cost of the pile caps are estimated to be slightly above the cost of a spread footing foundation system that would be used in a traditional solid ground building. The increase is about 20 percent between the pile caps and the spread footing foundation. Using an allowable bearing pressure of 4,000 pounds per square foot for footings on a traditional solid ground site, the total bearing area (based on the weight of the building 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 49 of 58 November 12, 2007 KlEINFELDER at 105 million pounds) would be about 2,600 square feet of footing. Using a footing thickness of 4 feet, the total cubic feet of footing would be 10,400, or about 390 cubic yards. At about $450 per yard to construct the footings, the cost would be about $180,000. The 20 percent increase for pile caps would be about $36,000. 8.2.4 Landfill Related Improvements Costs for required improvements to the landfill cap will vary depending upon the thickness and nature of soil material required to be placed. Low permeability soil materials may cost $2 to $3 per square foot in place. Soil fill used for an erosion layer will be more typical of soil fill used at conventional construction sites. For a nominal thickness of one to two feet this cost should be less than $1 per square foot. The costs for placing geogrid material such as Tensar BX1300 Geogrid beneath street areas is anticipated to be about $22 per square yard, including 12-inch overexcavation of subgrade, placement of the geogrid, and replacement and recompaction of the overexcavated material. 8.2.5 Operations and Maintenance Based on our experience, we anticipate that the operations and maintenance costs associated with structures and infrastructure constructed over landfills to be 150/0 to 250/0 higher than they would otherwise be at non-landfill sites. 8.3 ENVIRONMENTAL COST ESTIMATES 8.3.1 Environmental Cost Estimate Summary Additional costs for developing the site based upon environmental concerns are generally related to additional construction costs, permitting modifications, and additional monitoring and reporting costs. These costs, which are related specifically to the presence of the landfill, are estimated as follows: 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 50 of 58 November 12, 2007 KlEINFElDER 9 CONCLUSIONS Based upon data collected during this investigation, it is our opinion that, from a geotechnical standpoint, the site can be developed for construction although very high initial foundation costs as well as continuing maintenance may severely impact the economic viability of the project. It is important that the unique and problematic subsurface conditions of this site be properly considered in design. Based on the results of our research into this and similar sites and projects, the primary geotechnical considerations affecting the project are: 1) devising a means for mitigating the effects of the extremely large total and differential settlements associated with the decomposition and compression of the refuse material, and 2) development of a foundation system capable of transferring the building loads to the weathered bedrock materials underlying the refuse material. In our study we have considered several deep foundation alternatives including driven piles and drilled piers or caissons. The drilled pier alternative was considered to be impractical due to the high construction cost and special handling costs associated with the large amount of refuse material that would be accumulated during the drilling. Thus, we have concluded that a feasible deep foundation alternative to support structures is a system of piles driven into the clays, sands or weathered bedrock materials underlying the Bay Mud. Shallow mat foundations, such as those used for the restroom buildings at the site, may be used for small or lightly loaded structures. Also of primary concern is the mitigation of the problems associated with the differential settlement within the landfill surface and also between the pile supported building and the surrounding soil. Differential settlements are expected to disrupt pavement utilities, and subgrade supported structures even with mitigation measures to reduce differential settlement at the surface incorporated into the design. The design will also have to incorporate provisions to allow for utilities and subgrade supported structures to interface with the pile supported building. As previously discussed, the soil cap was found to vary from 1 to 14 feet in thickness. In addition, a continuous clay layer that is normally associated with a landfill cap was 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 55 of 58 November 12, 2007 KLEINFELDER · review of previous geotechnical and environmental investigations at the site, . the observations of our engineers, and . our experience at this site and in the area. The literature review does not provide a warranty as to the conditions which may exist at the entire site. The extent and nature of subsurface soil and groundwater variations may not become evident until construction begins. In addition, the subsurface profile may have changed since the performance of the exploratory borings due to settlement. It is possible that variations in soil conditions could exist between or beyond the points of exploration or that groundwater elevations may change, both of which may require additional studies, consultation and possible design revisions. If conditions are encountered in the field during construction which differ from those described in this report, our firm should be contacted immediately to provide any necessary revisions to these recommendations. It is the client's responsibility to see that all parties to the project including the designer, contractor, subcontractors, etc., are made aware of this report in its entirety including the Additional Services and Limitations sections. This report may be used only by the client and only for the purposes stated, within a reasonable time from its issuance. Land use, site conditions (both on site and off site) or other factors may change over time, and additional work may be required with the passage of time. Any party other than the client who wishes to use this report shall notify Kleinfelder of such intended use by executing the "Application for Authorization to Use" which follows this document as an Appendix. Based on the intended use of the report, Kleinfelder may require that additional work be performed and that an updated report be issued. Non-compliance with any of these requirements by the client or anyone else will release Kleinfelder from any liability resulting from the use of this report by any unauthorized party. 84166/ (PLE7R478.doc) / jmk Copyright 2007, Kleinfelder Page 58 of 58 November 12, 2007 u =? w I- C) ti5 .~ ~ ~ W :::l I- 0 ::i >- D.. :5 in ~ C) CCI .s 6 w (!) C) :> .~ z <.ci w w W I- lD ::i ~ D.. co 00 in I- ~ U g' w .s a Ol ~' .~ D.. Ifi .....' W is I- 0 ::i <( D.. u1 in ..... ~ U) g' c .s E Ol :::l .~ g ..; 0 W >> ~ :2 ..J W D.. :::l .!!! :g Ui Ol Ol CCI :..._= .5 Q) Ol (J) .~!;::"C MXl: WT""CCI ~~,~ D..~E in~~ ~~o CCI-O E~-:-:: -;xu .~.;..: Li.i N);:::! WcolJ.. 1-019 ~<(<( D..Q)U inz- ~(J) CCI';": .5~ x 00 .. ~ff:a <W~ ~~~ 09 w:;; :Co U~ <.:J !=dl <E: Son Francisco San Francisco Bay ...l <( :::J I- a. w U z Ol 0 .9; U r-.: .:.: W :::J ~ 0 a. >- in ~ <lJ g' 6 ..5 W Ol C> .9; >- cO ffi W to ~ <.0 ..J T"" a. ~ in U5 <lJ I- Ol U 113 W ..5 a Ol tt: .9; a. iO T""I W C ~ 0 0.. ~ in T""I @, In 113 c: ..5 E Ol :::I .9; (.) ...t 0 W 0 I- >- <( :a: ..J Qi 0.. :::I in .!!l <lJ In g' Ol E :a -; Q) a. '" oo ."':'T"" "C MXc: ~~113 <(...,.I.~ ..J.....c: 0..<lJ<lJ ">.E :g ti5 ~ g'~g Ett:-::": -;xu .~.;..:w ~'X:! I-OOl.L .....010 ::J<(<( a.Q)U inz., ~oo 113<+-: ..5& x UJ ....." Wooo C>l.Ltt: <(wo.. :a:tt:", -xo cot::: wwo :c:co UU~ <(<(.:J i:l=d> <(<.eo. ~" ~ / REFERENCE: PLATE DRAWN BY: LGS REVISED BY: 7133 Center Suite 100 Pleasanton, CA 94566 (925) 484-1700 (925) WW'N.kleinfelder,com CHECKED BY: DATE: RJD I APPROVED BY: I ADMINISTRA TIVE DRAFT OYSTER. POiNT REDEVELOPMENT FRANCSICO, CAUFORNIA FILE NAME: PLATES Au by PLOTTED: Aug 2007, 8:51am, lsue (f) u o -I l- t.) W O'l (,J) .9:; X ~ .:-: I:! ;:) ::; ~ Il. <( iJj -l <Il ~ <5 ..5 w O'l C> .9:; >- l.O ffi w to j ~ Il. ~ iJj (j) <Il I- O'l U co w ..5 a O'l 1:1:: .9; Il. ,,0 .....1 I:! 5 ::; 0 Il. C3 iJj I <Il ..... C) 2 co c ..5 <Il C) ~ .9; (,) ~ 0 w 0 I- >> ::; ~ Il. ::J iJj .!!2 <Il Uj 0') O'l co ._5 ..5 0') Cii a. I'-- en .-;0..... "C (")XC w.....co 1-..... ::;<(I~ 1l.<Il<ll ">.E (/)-::J <Il en (,) 0')..0 coE~9 1:1::.. ~XU .9;';":w fjx:::! I-OOLL .A" 0 IC ::i<(< Il. <IlU iJj~ ~en co.;..: ..5~ X (f) ....., W(,J)o C>LLI:I:: <Wll. :21:1::1'-- -Xo oor::: wwo 55~ <(<(.:.i I=I=~ <(<(a.. APPROXIMATE AREA OF EXCAVATION SUIIIIP2 APPROXlMA TE AREA Of INDUSTRIAL UQUID WASTE DISPOSAL, 1966 THROUGH by Drainage Channel Present Shoreiine Section LocaUon" WEST BASIN EAST BASI.Y / Pier B SUMP; APPROXIMATE AREA Of' SCALE (feet) SAN FJJAJVCISCO BAY REFERENCE: PES Inc. Cross " Joint Technical Document dated March 2000. PLATE BY: LGS REVISED 8Y: CHECKED 8Y: DATE: RJD I APPROVED BY: I PLOTTED: Aug 2007, 8:51am, lsue f.fJ f.fJ W Z :::c: u :c I- a.. Cl <( .9; U r--: W I- :3 a.. in Q) ~ <5 .s W Cl c:> .9; :> to ffi W (i5 ~ (0 ..J .... a.. ~ in en Q) I- Cl U 1tI W .s a Cl Il:: .9; a.. Lri ....1 W i5 ~ c a.. <3 in 1 Q) .... Cl 2 1tI C .s Q) Cl ~ .9; 0 -.:t 0 W C I- :>. <( :lE ..J (j) a.. ::l in .!!.! Q) u; Cl Cl 1tI '_= .s 0> (j) c."f.fJ .-:-.... "C (V') Xc w....ltI I- ....1(1) :3<(1: 0..Q)Q) ..>.E g: en i3 0>"0 ltI1i)g Ell::.. -;,xu .9;~w ~)(:::! I-oou- .....010 :::i<(<( a.. Q) U in~ ~f.fJ 1tI-+': .s~ x en ....., Wf.fJo c:>u-Il:: <(wo.. :lE1l::" -xo ocr::: wwo :r::r:~ ~~:J j::j::~ <(<(a.. .:..: :::::l o >- :3 PVEST BASIN EAST BASIl'{ SA1V FRANCISCO BA Y \ \ \ \ LGS BY: REVISED BY: CHECKED BY: DATE: Df,3]naga Channel Cap Thfcl<ness Contour in Feet Present Shoreline ApproxirnatEt Exient of Landfill Cap - q -- ApproxJrnate Trace of Gas Bamer Tn:ncn .J'v/'~/',../'".,- Cement-Bentonite Trench " i " i I ; I I " I Bey Mud leachate Cut-off Trench A.pproximate Drainage OlJtfaR LOC3tion 1iI",,""~:;;1I' UmilsofWaste APPROXIMATE SCALE (feet) REFERENCE: PES inc. uClosure If Joint Technical Document dated March 2000. PLA TE Center Pleasanton, PLOITED: 2007, 8:52am, lsue m I- U W O'l m .9; x r--: w I- ::5 a. ~ ;:) o 5 100 BO 50 40 20 o -20 in ll) ~ 6 ..E w O'l C) .9; >- to m w <0 I- (Q <( r ...J -.:t a. co in (j) ll) I- O'l U l\1 W ..E a O'l 0::: .9; a. i.O ....1 ~ 5 ::5 c a. j in rl ~ u; l\1 1: ..E ll) O'l ~ ' .9; u ..t 0 w C I- >. <( ~ ...J (j) a. :::J in .!!.! ll) U; O'l 01 l\1 ._= ..E 01 Q) Q.I"--m .'":'''1''" "0 M)(c::: w....l\1 1-"1"" ::5<(I~ n.ll)ll) ..>.E ~(j)~ 01..0 l\1'd;g Eo::: .. ~xu .9;';":w ~><= I-COLL ...,.olC ::i<(<( e.ll)(J in~ ~(/) l\1";": .5~ x m....., wmo C;>LLo::: <(we. ~o:::" -xo ;:: o o ~ ,.:..i m 0:: 160 140 120 100 80 60 40 20 o -20 SECTION C-C' NotM: 1) Rllfar 10 P I ate 2 for !oc:atIcn and or!&rltaoon ot !6CliQ(1.!l 2) Verllcai E~on:: 100! 40" ,2,5x 3) Th& r1.Jbbish flU is overlain ~ a soil cap o1vsl'jlr,g :J1lcj,OO$$, qwfir, and comj;X)1liOcn, 4) ~ng stJ~ .v~ lak8n!'rom tne "hydrograp~jc map of Oyster Palrrt: Msrln&w ~red by Towill, Inc. for Brlan4Cangu..Fooit; &!~ dalA!ld March 11, 197&, 5) ~ idooJlz~ 0011 proffletl ara cormructed 'oy direct ioterpdation 00tw00n. t6frt borl.ng8 drilled at varloua spadngs, The IIr~ ~nl} me various soli and rock ~ wera done for $Chemsttc lIlu$lJtlot; ~i onlY, The- proffle$ should not be ~ as a<:curafa rep~ of llCtu~ ffakj coodltionlS.. 6) No Wlnte foond In fllJ rot ~la GW~Sa and GW.9a. PES Inc. Cross 11 Joint Technical Document dated March 2000. BY: REVISED BY: CHECKED BY: DATE: 20 0- -20 160 140 120 tOO 80 60 40 ~ 160 j40 j2D W'iJ.fit'ilc 100 80 60 40 20 MUG [) -20 SECTION ,A.-A' 160 140 120 i 100 l..i... 80 60 4-0 20 0 -20 100 80 60 40 20 o -20 180 140 120 SECTION 8-8' [} 100 :LOG +00 300 500 BeG N-ote: Scales are approximate PLATE RJD BY: PLOTTED: 2007,8:53am, lsue UJ UJ W Z ~ u :c I- o :J :a: >- 0') <( ,9; m r--: ~ W :J ~ 0 a. j in <D ffi W (i5 ~ (0 -J ..... a. ~ in Ui . ~ ~ e.. ::s in .!!! <c Wrcu 1-..... <(......I!! -J.....c e.. .E Ul-::s <::! I-C:Ou. ...... 010 :::i<(<( e..<uu ;n~ ~UJ Ill';": ..5~ X UJ ....., wUJo e>u.IX: <(we.. :!:IX:"," -xo o or::: wwo ::J:::J:~ ~~:i I=l=~ <<0... Shor\JHna SAN FRANCISCOJ1Al' APPROXIMATE SCALE Inc. uThickness U Joint Technical Document dated March 2000. PLATE BY; LGS REViSED BY; CHECKED BY: DATE: RJD BY: Al.lg 2007, 8;55am, lsue 0) .9:; ~ W ~ a. in (I) 0) ro .E .~ ro - ~ ~ ..J ro a. "C in c: (I) ro 0) > ro (I) .E Qj 0) 3: .9:; C> U'i W I- ::) a. in (I) 0) ro <5 .E w 0) C) .9:; :> ..t z w W I- Ui <( U ..J :i: a. e.. ~ ~ 0) C> ro <0 .E (Q "("" 0) -.:t c."'CX) ~><2 w"(""(.) ~"(""~*' ....l<(lo... e.. (I) e.. ..~ :gent:: 0)..0 E~~ _ 0:: . 0) X ..J C. .. . ......"(""w fj><~ I-CX)U- A 010 ::J<(<( e.. (I) U in~ ~en ro";": .E~ X en....., wenO C>U-o:: <(We.. :EO::", -XO CCr::: WWO 5l5~ <( <C,J l=!=~ @ <(<(ll. .:-: ::> o >- <( ..J GW-13a Compound Concentration (l.l9/L) Benzene 32 Ethylbenzene <0.7 Xylenes <0.7 Chlorobenzene 120 Naphthalene <7.1 GW-12a Compound Concentration (J.lg/L) Benzene 77 Ethylbenzene 0.6 Xylenes 1.6 Chlorobenzene 100 Naphthalene 7.9 GW-8c Compound Concentration (J.lg/L) Benzene NA Ethylbenzene NA Xylenes NA Chlorobenzene NA Naphthalene NA GW-9a Compound Concentration (J.lg/L) Benzene NA Ethylbenzene NA Xylenes NA Chlorobenzene NA Naphthalene NA MW.5 GW-17a Compound Concentration Compound Concentration Compound (jJg/L) (l.l9/L) Benzene NA Benzene 0.5 Benzene Ethylbenzene NA Ethylbenzene <0.5 Ethylbenzene Xylenes NA Xylenes <0.5 Xylenes Chlorobenzene NA Chlorobenzene 8.8 Chlorobenzene Naphthalene NA Naphthalene <5.0 Naphthalene " , , GW-11 a Compound 1~'iIlu <Il~... - 'n,- ,,"'- Compound Concentration (j.lg/L) NA NA NA NA NA Concentration (l1g/L) 1.9 1.5 2.9 4.4 <5.0 Concentration (j.lg/L) ,-~"" ..,... _ww __ Concentration (lJg/L) Compound Benzene Ethylbenzene Xylenes Chlorobenzene Naphthalene 1.1 <0.5 1.0 39 <5.0 Benzene Ethylbenzene Xylenes Chlorobenzene Naphthalene I Benzene Ethylbenzene Xylenes Chlorobenzene Naphthalene / GW-4a Compound <0.5 <0.5 0.7 <0.5 <5.0 / . { Concentration (l.l9/L) ., " . ... " Benzene Ethylbenzene Xylenes Chlorobenzene Naphthalene .' <0.5 <0.5 <0.5 <0.5 <5.0 ~f" ~~. .:: ). GROUNDWATER ELEVATION AT WELL (feet) GROUNDWATER ELEVATION CONTOUR (feet) ~lf!' . , " 'x, " ..' ,:~:, '.C', ............:'..,..,. . _. : '.,~ , '"' ' ".. '"',," , , ~~i~l' 1liJi2l " ",~ '~ ":';;~~1'~:<.,.,.,. " '. """~'.~'~ ":; ./ '~"-'r;~:"- <X NOT DETECTED at or above the indicated laboratory reporting limit '::""/::.',:,,::~ .:,' "",:::::2Y ::-6'__ NA NOT ANALYZED - -,--~- ",' " BOLD V ALUE IS ABOVE MACLs -- ,':::2.'::2'.. ',' -"=" -= -7 ;:" 'L '.. GW-3a :' -<c: Compound Concentration (J..Ig/L) Benzene 70 Ethylbenzene 510 Xylenes 2350 Chlorobenzene 340 Naphthalene 140 GW-5a Compound Concentration (J..Ig/L) Benzene <0.5 Ethylbenzene <0.5 Xylenes <0.5 Chlorobenzene <0.5 Naphthalene <5.0 APPROXIMATE SCALE (feet) " - ".. ,C'.::!,".::.'.":.\. --." -, 7/ ''', ,C:::,,' ~ ... ., ":Jt,.~w~;: I. - ~'"",- -"::.-.... ",,' ~//; I~~ ~ ~y _~\(~?8,! :. ,.. J- '''. .::.::::\c ~ .' '." ',' ' -,,::'-::' . .- ".....~." ,"." .. ,"", --,,": t' ,,,:,'J, -<r:, - .v..... .. .. ,".", ,':1 ":":';1'-: " 29 0 1l I GW-7a GW-10a GW-15a GW-6a GW-1 a Compound Concentration Compound Concentration Compound Concentration Compound Concentration Compound Concentration (J.lg/L) (J.lg/L) (J.lg/L) (J..I9/L) ( J..Ig/L) Benzene <0.5 Benzene 20 Benzene 3.7 Benzene 40 Benzene 52 Ethylbenzene <0.5 Ethylbenzene <4.2 Ethylbenzene <0.5 Ethylbenzene 41 Ethylbenzene 18 Xylenes <0.5 Xylenes <4.2 Xylenes <0.5 Xylenes 10.5 Xylenes 248 Chlorobenzene <0.5 Chlorobenzene 63 Chlorobenzene 20 Chlorobenzene 36 Chlorobenzene 83 Naphthalene <5.0 Naphthalene 520 Naphthalene <5.0 Naphthalene 5.4 Naphthalene 96 REFERENCES: PES Environmental, Inc., "Monitoring Well and Point of Compliance Sampling Locations," dated March 2000. PES Environmental, Inc., "Potentiometric Surface Map, December 16, 2006," dated January 2007. DRAWN BY: LGS - - ill 7& ~ill_.!II_ iI."IllK!Il.ul!IINlUWWA IIUINl~ ANIU lUl :1111l rr" --II'l>!iI-;nid~" ,1!' I ~ __ __ __D. _~w. II .._..""_" n ii= ~:: "''''' ~ Ie D :;iilliill~ - ,u.... ____ PLATE REVISED BY: CHECKED BY: DATE: 7133 Koll Center Parkway, Suite Pleasanton, CA RJD I APPROVED BY 'l~TIVE DRAFT U I" 1 C:I"\ POINT ~.~.1\.?!!,! 1\ REDEVEL"", ""'_I' l SOUTH SAN FRANCSICO, CAL, '"" "..r EROJECT NO, 84166 I FILE NAME: PLATES"Auj;107.dwj;1 (925)i1Q1L~~"<Q ,","""'1M . , .. ;, 2007 PLOTTED: 10 Aug 2007, 1:21pm, Isue 84166 / (PLE7R478-Table 1.doc) Copyright 2007, Kleinfelder November 12, 2007 KLEINFELDER jmk . . Page Probe depth will correspond encountered waste in areas groundwater levels permit. Monitoring probes will be dri of 5 ed by_a to the depth to first where leachate or icensed Perimeter Monitoring Network . . Installation of gas monitoring wells or probes along the perimeter of the site at a frequency of no less than 1,000 feet. Increased frequency of monitoring points where structural features indicate increased potential for gas migration such as utility corridors leaving the site 20925 Monitoring The landfill gas monitoring program must be designed by a registered civil engineer to assess gas migration and potential accumulation in structures . ncluded as part of the overal prepare"'! gas LFGMP sign system the and 20923 . . . 20921 Gas Monitoring and Control During Closure and Post Closure COMPLIANCE REQUIREMENTS Allows for specific exemptions from prescriptive requirements. Implementation of a gas monitoring network and monitoring program during closure and post- closure. Requires substructural gas ventilation systems for all future construction that meet the following: . Methane <1.25% in structures; . Methane migration from the landfill <5%; CIl Toxic gases maintained below risk-based thresholds; and Monitoring/Control for 30 years, or until written authorization to discontinue is issued by the EA. . . . . . . . . 80 milliner under al 4" perforated pipe liner. diffused gases. 10,000 sf structures n 12" gravel base under SEe 20918 TITLE Exemptions DEVELOPMENT ACTION Table 1 Summary of CIWMB Closure and Post-Closure ReqUirements Oyster Point Landfi CCR Title 27 84166 / (PLE7R478-Table Copyright 2007, Kleinfelder November 12, 2007 KLEINFELDER .doc) jmk It . Page 2 of 5 Submit monitoring reports within 90 days of sampling. Implementation of reporting and control measures in accordance with Section 20937 if sampling indicates exceedance of trl9..ger levels . 20934 Reporting Monitoring Frequency . /II . Continuous structural gas monitoring for LEL Quarterly monitoring of Methane and trace gases. Increased frequency of monitoring if results indicate potential landfill gas migration . . Continuous monitoring for methane provided in subsurface and first floor for the LEL and at early warning levels. Contingency Plan for alarm conditions developed in PCMP. Monitoring reports will be submitted quarterly basis. Annual Reports will be performed for and monitoring modifications. system on wil will be 25 % of a be 20933 .. 20932 Monitored Parameters . Monitoring landfill gas for the lower explosive (LEL) and periodically, for trace gases im it . . . 4& Trace gases to overall LFGMP Post Closure Maintenance Plan (PCMP) will be developed for calibration, monitoring and maintenance requirements. Contingency Plan for alarm conditions will be developed in PCMP. Quarterly Monitoring and Calibration of the structural monitoring system will be performed. Continuous monitoring for methane will be provided in subsurface and first floor for 25% of the LEL. 1 subsurface (monitor only). 1 first floor methane monitor per room with minimum 5,000 sf coverage (monitoring and alarm). Alarm set for alert. be included as part of the . .. 411 Calibration and maintenance monitoring systems. Quarterly monitoring of unoccupied structures . audible and emergency services COMPLIANCE REQUIREMENTS drilling contractor and logged by a geologist engineer in accordance with ASTM 02488. Maintenance of probe location maps construction details. Installation of a bentonite seal from the monitored zone. Structure Monitoring Installation of systems with structures. of automatic continuous monitoring audible alarms in all occupied structural . 20931 . 4& methane monitor per 0.000 sf .. . the surface to and or SEC TITLE DEVELOPMENT ACTION Table 1 Summary of CIWMB Closure and Post-Closure ReqUirements. CCR Title 27 Oyster Point Landfi 84166 / (PLE7R478-Table 1.doc) Copyright 2007, Kleinfelder November 12, 2007 KlEINFElDER jmk Page 3 of 5 SB.ecifies re..9.uirements for removal of structures 21137 Structure Removal ID Signage and public notification of landfill closure and alternative waste disposal facilities. The site must be secured and components of monitoring and control or recovery systems shall be protected from unauthorized access. . ID . Site security will be provide 24 hours per day by hotel security personnel. Monitoring points will be secured in locked rooms or out of reach from public. Ventilation equipment will be secured on roof top level or in locked accessory building. No structures from orl9.inal landfill 02erations 21132 21135 Landfill Emergency Response Plan Review Site Security ID Submittal of the Emergency Response Plan SMCHSA and RWQCB review. for ID . ID 21130 Emergency Response (II ID Provide occupied spaces Implement a remediation days; and Place incident in operational corrective actions. ERP to be submitted with PCMP Verify results; Submit a letter to the SMCHSA and RWQCB within 10 days to describe the nature and extent of the exceedance and interim corrective actions to be taken; and Construct an appropriate long-term gas control system modification designed by a civil engineer. Development of an emergency response plan to identify potential occurrences which might threaten the public health or environment and present emergency response procedures, sequences and schedules notifications, responsible parties and reporting requirements. The ERP will be amended as necessary as conditions change or if events indicate potential emergency situations not provided for in the plan. III record with Emergency response developed in the PCMP minimum requirements: · Notify emergency services agency; · Extinguish open ignition sources; III Evacuate the building or parking structure · fresh air to vent or exhaust . plan within 60 . procedures will be to include the following SEC 20937 TITLE Control iIII III COMPLIANCE REQUIREMENTS If regulatory levels are exceeded during monitoring, actions to be taken include: III Protect human health and safety and environment; Notify the SMCHSA and RWQCB within 5 days of detection of the exceedance; <II the gas . DEVELOPMENT ACTION Contingency Plan for emergency response PCMP alarm will be conditions and developed in Table 1 Summary of CIWMB Closure and Post-Closure ReqUirements. CCR Title 27 Oyster Point Landfil 84166 / (PLE7R478-Table Copyright 2007, Kleinfelder November 12, 2007 KlEINFElDER .doc) jmk Page 4 of 5 Design and implementation of landfill gas and leachate control measures to prevent public contract, control vectors, nuisance and odors. . . Post Closure Maintenance Plan (PCMP) wil developed for calibration, monitoring maintenance requirements. Contingency Plan for alarm developed in PCMP. Des!9.n details for the 2ile installation conditions wil and be 21160 Landfill Gas Control and Leachate Drainage and Erosion Control 49 Inclusion of drainage and erosion control plans in conjunction with the final grading plan to ensure the integrity of post-closure land uses, roads and structures and prevent damage to gas monitoring and control systems, safety hazards or exposure of wastes. e . . Surface drainage to direct flow drain system for paved areas 3% minimum slope for landscaped areas. Drainage and soi erosion plan be and to be submitted soil and 21150 . . 49 Final slopes will be less than 1 be stable through specific analyses. Any slope failure wil and RWQCB be reported to the SMCHSA . . connection Maximum slope 1 horizontal. Skirt wall calculations to new storm 21145 Slope Stab ity .75 or shown to slope stability Development of a final grading plan to indicate the final topography and document slope and thickness of the cap and provide the basis for settlement monitoring. 49 . . . 3% minimum Settlement PCMP. Details of foot slope for surface drainage analysis per the overall vertica per 2 landfil feet 21142 Final Grading . ED e asphalt course; 12" vegetative soil cover; and 4' minimum landscaped area 2" sand footings. Erosional . 12" e 2" layer consist one of the following reinforced concrete slab; surface with 4" asphalt base e COMPLIANCE REQUIREMENTS associated with landfilling operations. The final cover will provide with a minimum of maintenance, waste containment and will control vectors, fire, odor, litter and landfill gas closure consistent with post-closure land use. The final cover will consist of a foundation. low permeability and erosion resistant layers. e . e e . 4& that 24" 6" gravel layer. 4" perforated PVC pipe 40 mil HOPE liner. under concrete Slabs pile caps or 21140 Final Cover e DEVELOPMENT ACTION might require removal are present. foundation layer. SEe TITLE Table 1 Summary of CIWMB Closure and Post-Closure ReqUirements. CCR Title 27 Oyster Point Landfi 84166 / (PLE7R478-Table Copyright 2007, Kleinfelder Change of Ownership During Closure or Post- closure Maintenance .doc) jmk . CD 21200 21190 Post-closure Land Use . Restriction of post-closure land use to: CD Protect public health and safety; CD Prevent public contact with waste gas and leachate; and · Prevent landfill gas explosions. Any change of ownership will include full disclosure of the known conditions of the landfill, post-closure operational standards and conditions or agreements associated with compliance. The SMCHSA will be notified any ownershi12- chanQe. Page 5 of 5 within 30 days of . November 12, 2007 KLEIN FELDER There are no plans to change landfi from the City. Land is leased Francisco ownership Control of future land use by deed recorded with the County Recorder. Preparation of a post-closure maintenance plan to document procedures for reducing impacts to public health and safety and maintain environmental control systems. It will address: · Site security; II Gas monitoring and control; CD Leachate monitoring and control; and Cap monitoring and maintenance. andfil . II It 21180 21170 from Closure activities Gas monitoring and control; Cap monitoring and maintenance; Inspection and repair of the landfill; Procedures and schedules for inspection for leachate seepage, erosion, vegetation inspection, settlement; and drainage monitoring; .. Emergency Response Plan; and ~ Contingency Plan. Modification to site restricted by agreement. Design Plans and Specification are with this Table for Post Closure Use this Table Surface sealing of cap penetrations is proposed using cement/bentonite grout. Modification to site restricted agreement. The site specific PCMP will address It Site security; · Cost Estimate for Post CD . . . the City of South included ease San Post-closure Maintenance Recording . CD restriction . by ease G DEVELOPMENT ACTION excavation areas are included with SEC. TITLE COMPLIANCE REQUIREMENTS Table 1 Summary of CIWMB Closure and Post-Closure ReqUirements Oyster Point Landfi CCR Title 27 84166/ (PLE7R4 78- Table 2.doc) Copyright 2007, Kleinfelder November 12, 2007 KLEINfELDER 21090 21090 21090 21 84"0 Closure and Post-Closure Maintenance Requirements for Solid Waste Landfills Closure and Post-Closure Maintenance Requirements for Solid Waste Landfills Closure and jmk Page of 2 CQA Grading to prevent ponding, erosion & (3% min. positive slope). required to present procedures to . . . . .. Site specific CQA Plan to be subm Surface drainage to direct flow to new storm drain system paved areas. 3% minimum slope for landscaped and soil areas, Attached drawings provide drainage plan Soil erosion plan to be submitted itted with construction Discharge of liquids will address: .. leachate/ gas condensate; lit dust control; and lit irrigation run-on for COMPLIANCE REQUIREMENTS final cover consisting of the following: 1 :1.75 maximum slope or slope stability analyses; 2-foot minimum foundation layer to control settlement; 1-foot minimum low K layer (10-6 em/see) layer; and 1-foot minimum resistant layer. Post-Closure Maintenance Cost Estimates to covers Cover maintenance plan & cost includes: \II periodic leak search; · periodic inspection of cover, erosion, low k damage, drainage, damage & settlement; Prompt cover repair; and Vegetation maintenance. erosion . . \II is vegetated restricted and estimate that 2" sand under concrete slabs, pile caps or footings. Erosional layer consist one of the following: · 12" reinforced concrete slab; It 2" asphalt surface with 4" asphalt base course; · 12" vegetative soil cover; and · 4' minimum landscaped area ~ Maximum slope 1 foot vertical per 2 feet horizontal. The site specific PCMP will address: .. Site security; CD Cost Estimate for Post Closure activities; · Gas monitoring and control; \II Cap monitoring and maintenance; · Inspection and repair of the landfill; · Procedures and schedules for inspection for leachate seepage, erosion, vegetation inspection, settlement; and drainage monitoring; and · Emergency Response Plan III Contingency Plan. Construction Quality Assurance address discharge of liquids (CQA) Plan and PCMP wil SEC. 21090 TITLE Closure and Post- Closure Maintenance Requirements for Solid Waste Landfills . A \II . . . . . . . DEVELOPMEMT ACTION 24" foundation layer. 6" gravel layer. 4" perforated PVC pipe 40 mil HOPE liner. Table 2 Summary of SWRCB Closure and Post-Closure ReqUirements Oyster Point Landfi CCR Title 27 84166/ (PLE7R478-Table 2.doc) Copyright 2007, Kleinfelder November 12, 2007 KlEINFElDER 21 21160 090 jmk Closure and Post- Closure Maintenance Requirements for Solid Waste Landfills Landfill Gas Control and Leachate Contact TITLE Post-Closure Maintenance Requirements for Solid Waste Landfills Closure and Post- Closure Maintenance Plan Requirements Closure and Post- Closure Maintenance Standards for Disposal Sites and Landfills Gas Monitoring and Control During Closure and Post-Closure Recording detailed maps Leachate monitoring & control Page 2 of 2 III e e . . III lit III . III CD lit .. lit 40 mil HOPE liner under all structures 4" perforated pipe in 6' gravel base under liner. Roof top ventilators to exhaust diffused gases. 1 subsurface methane monitor per 10,000 sf (monitor only). 1 first floor methane monitor per room with minimum 5,000 sf coverage (monitoring and alarm) set at 25% of the LEL. Post Closure Maintenance Plan (PCMP) will be developed for calibration, monitoring and maintenance requirements. Contingency Plan for alarm conditions will be developed in PCMP. Health and Safety Plan, and Construction Quality Assurance (CQA) Plan will be developed for excavation areas. Continuous monitoring for methane will be provided in subsurface and first floor for 25% of the LEL. Trace gases to be included as part of the overall LFGMP. Design details for the pile installation and excavation areas are included with this Table. Surface sealing of cap penetrations is proposed cemenUbentonite grout. As built drawings will be prepared and submitted days of completing work. Long term settlement analysis per the overalllandfil PCMP within 60 using 20921 Gas monitoring & control Survey to establish initial topography, set monuments & prepare iso-settlement maps every 5 years. 21090 21769 Precipitation & Drainage Plan to describe means of minimizing infiltration recharge. . . Settlement analysis per the overal Attached drawings provide drainage plan andfi PCMP COMPLIANCE REQUIREMENTS document that construction meets requirements. documents SEC DEVELOPMEMT ACTION Table 2 Summary of SWRCB Closure and Post-Closure Requirements. CCR Title 27 Oyster Point Landfi '" '\. ~ 5 f\ I w,reh"} -v/ \\ , \ \ ' ) rOffice' ! Tower / ~/ I k----..--------- -- --- --.-- Warehouses ----'---- e;Yc;;;!>;;[i;-;o;;l~~ri5iOn - -- ---- __I i I --- ~- --~- 100 C) 200 400 feet AUG UST 2006 LEASEHOLDS a ~~ ~, Parcel 3 1.2 acres FRAMEWORft PLAN -- , ~, __ 0 100 200 400 feet 9 AUGUST 2006 ~ _ _. O ~ . 0 0 ~~ 0 N rt ~D ~•J O 7 r ~~ a~ T \V ~^ ~ _. CD _. 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S r~, 1 «... ~; ~ , ~~x ~~ ~( ~~' ~ "~ ~~ ~~ .~ II''i ~ i 3 I . ~.. ~.+ ~ t v m 0 o `' n ~ _~.. ~' _ ~ v o ~ ~.~~+~ .~ _ __ ~ '~ ~~ is ~ .. _ ; -_ - AT'~: April 16, 2008 T~ e 1-Ionorable Mayor and City Council F s Sharon Ranals, Recreation and Community Services Director SST C'T® APPRC)VAL OF TI-IE JUNIPERO SE BOULEVARD REMEDIATION REPLANTING CONCEPTUAL PLAN ~ ~l~i ATI: It is reeo mended that the City Council revie~~ and approve the Junipero ~"erra boulevard R.ernediation replanting Conceptual l~°lan ~vvhieh vas reviewed and reeorn ended. by the l~arits and reereation Commission at their regular meeting of January 24, 200. I~~CK~r~~.Tl~I~: Junipera Serra Boulevard was one of several roads built along the Peninsula before the age of freeways. It became a state highway (Route 23 7) in 19 ~ 6, receiving the State Route 117 designation in 1964, only to be deleted from the state highway system the following year. Today tl~e road is under the ~L1rlsdlctloll Of t11e Clty, alld is a Ina111 thol-OUgllfare for local traffic. The boulevard extends 1.7 miles from Avalon Drive at the south, to Flickey Boulevard at the north. There are approximately 271 trees planted in the median islands, including Monterey Pine, Stone Pine, and Incense Cedar, many of which were planted. decades ago. The condition of the median, including pavement and curb disruption caused by tree roots, has deteriorated over the years. The boulevard is greatly in need of upgrade. Unfortunately, a disease ltiiown as "Pine Pitch Cal~lcer" has billed and is infecting Monterey Pine trees not only in the City of South Sa11 Francisco, but throughout the state of Califonlia from Mendocino to San Diego. At present there is no Known cure for this disease. The disease has most impacted the not Ahern end of the boulevard, and is progressing toward the south. In an effort to address the decline of numerous trees an the boulevard, and the general deterioration of the median, City Council approved an allocation of $50,000 per year, tentatively for tl-~ee consecutive years, toward the problem. The extent of the needed improvement is so extensive, and the area so significant, staff ha.s detern~ined a comprehensive master plan for the area is needed. Tl-~e goals are to address long term maintenance issues; create a cohesive appearance that also allows far il~terest in Staff Report Subject: Approval of the Junipero Serra Boulevard Remediation Replanting Conceptual Plan April 16,2008 Page 2 variation of plant material; provide accent and color; specify hardy plants and trees that are tolerant of drought, vvind, and fog; and to utilize South San Francisco's Centennial Tree, the Coast Live Redwood. In the current budget year, a portion of the Junipero Serra funding was used to contract with Callander Associates to work closely with staff to prepare are-forestation Inaster plan to meet desired goals and deternline a cost estimate. As evidenced with Centelmial Way, the preparation of a Inaster plan that includes cOlnmunity input and cost estinlates can be very helpful in applying for grant funding. The Parks and Recreation Comnlission reviewed and approved the Junipero Serra Renlediation Replanting Conceptual Plan at their regular Ineeting of January 24, 2008. The Connnission recOlwnended the plan be reviewed and approved by City Council. The cost estimate to implement the plan, including design, engineering, construction drawings, delnolition and relnoval, drainage improvelnents, irrigation, soil analysis and anlendment, trees and plant material is $948,000. With no funding source yet identified, a strategy of phasing the project is recommended, with implen1entation to take place over a period of years as funding becomes available. Inlplelnentation would likely proceed from north to south, addressing areas of greatest need. If a $50,000 allocation is approved in the 2008-09 budget, these funds could be used toward Phase I, or possibly as a match to leverage grant funds. Callander and staff will continue to seek funding sources. CONCLUSION: Junipero Serra is not only a critical artery for traffic, but a beautiful, forested avenue that contributes to the lUlique character and history of South San Francisco. The necessity of addressing the aesthetic decline brought on by disease, creates an opportunity to redefine the boulevard with a nlore cohesive landscape that includes careful selection and placenlent of a palette of trees and shrubs that are appropriate as well as beautiful and sustainable. Mark Slitcher of Callander Associates \vill attend the City Council Study Session to present the details of the re- forestation plan. ~<:) I ( e:;:<'" Approv~d: ,; Sharon Ranals Director of Recreation and Comlnunity Services Attachments: Junipero Sena Boulevard Conceptual Plan Infonnation Packet Power Point Presentation prepared for the City of South San Francisco Summary Estimate of Probable Project Costs Junipero Serra Boulevard Tree Replanting Summary Preliminary Plan prepared on: 1/17/08 prepared by: KD/NR/MS Item # Description Qty Unit Cost Item Total Subtotal Bonding, and Traffic K · Estimate of Construction -. . -----------..--..-....--.- ---"'--..~-----"""_..__.- -- amounts, are on and is offered only as reference data. Callander Associates has no control over construction quantities, costs and related affecting costs, and advises the client that significant variation may occur between this estimate of probable construction costs Callander Associates Landscape Architecture, Inc. 07075SurnmaryPreliminaryPlanl-17.08.xls · copyrighted 2008 Calland.r Associates Landscape Architecture. Inc. Page 1 of 1 EXISTING CONDITIONS LEGEND CONCRETE PAVING . COLORED CONCRETE PAVING @ TREE SHRUBS/GROUNDCOVER TO BE REMOVED --0-- FENCE TO REMAIN TRAFFIC/REGULA TORY SIGNAGE el BRICK III STORM DRAIN INLET [g) ELEC TRICAL BOX * LIGHT POLE )':{ TRAFFIC SIGNAL OIl POLE MONUMENT SIGN TO REMAIN @ IRRIGATION BOX ~ ZONE ~ID NUMBER (SEE EXISTING TREE LIST FOR NORE INFORMATION) G PHOTO REFERENCE (SEE CORRESPONDING NUMBER IN PHOTO LOG) ID~, ,..2..t.'.,,! . .'28'..... . 2'1 .so- .,_. , 31 32 33 34 35 36 31 3e 3'l ZONE I - HIC.KEY TO KING eavs SPECIES 45 46 41 4e . 4<1 j 50 51 52 53 54 55 56 51 5e 5'1 60 bl b2 b3 b4 b5 bb b1 be b'l 10 11 12 13 14 I I I i i o OTHER UTILITY .,.,...... I ID~, eavs SPECIES ZONE I - HIC.KEY TO KING 15 PINE 'iE::.- ~: ~NI:.:.... ,.., 11 CEDAR .,e.:" . .. -c-roAR -.. '..'.; ... ,...... ..,....... 'II . ""'2 j '13 j '14 'IS ."'6 -'ri" .....9b _ '1'1 101 -10:2" .Ios. -104. ...'105.. lOb 101 _IC:::B.. ._ 10'1 110 III 112 113 114 115 116 111 Ill> 11'1 120' 121 122 123 124 i 125 : 126 121 12B 12"1 130 131 132 133 134 135 136 131 13B 13'l 140 141 142 143 14-4 145 146 141 14e> 14<1 150 ..piNE' PINE PINE CEDAR CEDAR CEDAR PINE PINE CEDAR PINE CEDAR CEDAR CEDAR CEDAR PINE CEDAR CEDAR . CEDAR CEDAR CEDAR CEDAR CEDAR PINE PINE CEDAR CEDAR PINE CEDAR CEDAR CEDAR CEDAR PINE CEDAR PINE CEDAR CEDAR PINE CEDAR CEDAR PINE PINE PINE PINE PINE PINE 5TONE PINE c.YPRESS PINE CEDAR , PINE PINE PINE PINE PINE 30' 25' 30' IB' 15' 20" 25' 30' 5' 20' 15' IB' 4' 15' 35' 2' B' 10' 10' 10' 12' 14' 25' 35' 12' 14' 21' IB' 22' 12' II' 35' 5' 35' 4' ti~~ ..so~ HEI5HT CIRCUM-F TREE CONDITION ERENa: ALIVE DECLININos I ......,.,-,.- 30 22' 40' 35' 35' ;20' 35' DEAD I I I I I I I I ...+..-. ,.. -., -. I I I I I I I I I I I I I I I I I I I I I I I I I =:==+2=. I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I I ZONE:2 - KING TO V4E5T60ROUGH CIRCUM-F TREE CONDITION ID~, eavs SPECIES HEI5HT ERENC.E ALIVE DECLININos DEAD 0'1 .......,... CEDAR _ )._ 5~-;:. :3' I j 1.'-."';;:.'.' ...PINE--" 3'-T ' -:;~... i--" . : I.,....,...."..,., ".......... PINE i 40; 5'-10'" .,....,...",... 0"_ ._ 1..." 'i..........,......,. -..,..,...., ...."C:: i 4' 2" ,................, 1"'05.' r 55' 5'-10" I -,........,... I"'?.t.' , . _, PINE i 55' 1'-1" ., di CEDAR ,. i 20' 2'-2" I ... . -T. i.'?'::'" CEDAR I 4' 2" I ,......._....,-- I.....,...,..,......, PINE ; 40' 10'. ..--. . i-.- ..+--..... 1._".""..,,_, ,....._, .. PINE 40' 1'-5" ------ '''.'..'C.'.'.' CEDAR 1 I I .--_. . ...... CEDAR 15' 2' I 1-...i5......- ..., PINE 40' 12' .. - " - __-i.__ ..._.... .,....'.~.,., CEDAR IB' 1'-5" I 15 . CEDAR IB' 1'-10'" I 16 PINE 40' 10" I 'm_. ___ 11 PINE ---- 50' '1'-10" I IB PINE 30' 5'-10" I 1'1 CEDAR 15' I 20' CEDAR 3' I .. ....... 21 i PINE I 22: CEDAR i ... -,.,-, ---._-- 2:3 i CEDAR i 24 i PINE -'-'-' I ~~:::j:=~_.- ~:~: .:~" i --.. I I 2e PINE I 2'1 PINE I 30 PINE ----..- I 31 PINE 40' 3'-6. I 32 PINE 40' 4' I 33 PINE 45' 5'-3" I 34 I PINE 40' 6'-6" I 35 PINE 50" 'I'-S. I 36 CEDAR 15' 1'-6" I _. 31 CEDAR IB' 2'-1' I 3e PINE 50' '1'-10'" -"-' 3'l PINE 25' 4'-11" I 40 PINE 25' 1'-11" 41 PINE 30' 6'-6' 42 PINE 40' 11'-10'" 43 PINE 25' 10" 44 CEDAR 10" 1'-2" 45 CEDAR 2'-3. I 4b CEDAR B" I 1'-.-. ~~~~=: 41 PINE '1'-<1. 4B CEDAR 1'-4. I 4<1 PINE '1'-1. I .... 50' CEDAR 2'-<1. I 51 CEDAR 3'-2. I 5 PINE b'-2. i I 5 PINE 35' 1'-6. I 5 PINE 20' 1'-2. I 5! CEDAR 12' 1'-11" I 5/ CEDAR 22' :3'-1. I 51 CEDAR 16' 2'-2. I 5B PINE 40' II' I 5'1 PINE :;) 20" 1'-4. I 60' PIN! 50' 1'-5. I .....---=t~~.= 61 PINE 30' 6'-5. I 62 PINE 20' 6'-10' I 63 PINE 25' 3'-1 I 64 PINE 20' 6'-10'" I 65 PINE 20' 1'-11 I 66 PINE 20' 1'-2" I 61 PINE 20" 4' I ID~, 33 34 35 36 31 3e 3'1 40 41 42 4:3 44 45 46, -"41. r .... 4B 4<1 50' 51 52 53 54 eEMJ5 SPECIES ZONE :3 - V4E5TBORO\JGH TO AVALON DEAD TREE CONDITION HEI5HT C:: ALIVE DECLINlNos ., .':i<::>' 20" ...... 15' 40' 40' 15' 20" 20" B' 15' 10" 20" 40' 40' i 15' i 15' i 15' i 15' 40' IB' 10" 20' i 12' j 12' 10" 30' 30' 0" 0" 15' 1'-11 '-2" 3'-2. 1'-1" 1'-11" 1'-4. 1'-6" 2'-5. 2'-4. 'I. 2'-0" 'I. 2'-B" 6'-B. ,2. Ie 5 0'" 4 10. 5 ,3. 1'-2" B" 1'-2. 1'-11" B'-2" 5'-<1. 4'-11" b'-O. 5'-2" ........ ..,........... .. .....-.....""....'.......-....... .. ~:: :~~~~..:..3:..::=~.. ::,:::,:: ::::l:::::: i .,..... i. _,._._ ......,.-... . .._. .......... . ---. ........ ... .,_...... ,_.,_..,_.................,... .,....,........... ,-,.,..,.., ..._,_........ ...-.- ........ ., . -.., .....,. ....--.-,- I ,_... ..-.....-... I I I I I I I I I I I I I I I I I I I I I I I ".. ,...............-. TREE CONDITION HEI5HT C=: ALIVE DECLININ6 DEAD ,J~""j ~~~ ~ ,...~:;.+ :~~: I.. :.._i."..:_.,..,_ 05 i EU<:;AL YPTU5 ' .:25' 1 2'-10. ' -I. : . i..-., ;_~:.l.. :::::::: .~:~:+::::: ..: ; ...._... . 06 ~., " 'piNE"'- ;-"20" i 4'-5" i I .. ,.,.....-- -.di. -.... PINE i "..25'.. 4'-11" .- r 1_.._.. ...'-- I'..OB. PINE i 25' 3'-B. I _ . . ........ 1.0;1. ..,. PINE r 30'- 4'-10. -",i.-.. 'I 'i"O ... PINE '30~ 4'-b" .-...,;.. i I.......i"'.'.' PINE i ,. 30' 3'-1" I.......,... l..m..~:.H..., ~..._...m___ PINE -- .. SO' 4'-10. -~ __ ~_m......_ ~ ~~~......~.__~...m......~.....: I.......,..,...., ,........,. ... PINE '~.... 25' 3'-10" I PINE 25' 3'-3" ...,.....-. ._..i--'....'... ...,..-.. ...,..'15..... ..,.., PINE 25' 5'-0'. .., ,,_. . t.'.....'...'( ........... I.......'......,.. 16 PINE ,_.... '''-.''''2''5'-'.. i'.-37:e;~.."'..~ I ....,... ".h PINE -, 25' 5'-3" .'i'............ ,-...............-. '-.ii PINE 25' 2'-<1. .......,..,.'1...,.,..., ,.-..,....,.... 1'1 PINE 25' 3'-2. ........., ,.. I 20' PINE 25' 4'-10. I 21 PINE 25' 4'-5. I 22 PINE,.:~:.. 3'-0"_..;.... ,11."._"_' ...._,.......,.., I ~:: C::R -'~ ~:=~~.. .. i.'" ,. ._"_m.._ ... PINE IB' 5'-5"." ..,.... ...... ...(....... .,......,...,...,.,... PINE" -,. .....".....'iei..... ._..'4~~2;..'......_,.., ...........,., _. ...,.. .1"'.-..1 ..,... PINE 20' 3'-0"" . I'" , .. ., ...,..,. PINE 20'" $'-~ I - -- - ~f~.. ~._... ~~, :,~ ~.....:~~-~.~ PINE .""'.-25; 1'-' ." ".:, 1"_" . :..: PINE 25' 2'-. I 1..lIl:i~~ PINE 25' 5'-10" I PINE 30' 4'-10. I CEDAR 4' 0"-3. ~~~~~~[~~~~:~fl~~:~j~~~~ ';_. PINE 30' 1'-10" PINE 20' 3'-6. ' .- . ~j~ :t!=:=~. .:..~. PINE 4'-4" I . PINE 3'-2. I PINE 5'-4. I CEDAR 2'-6" I CEDAR 0'-3" PINE .. 6'-0' PINE ..,. 6'-B" PINE 4'-5. PINE 4'-0" I PINE 4'-10".... ,I _..,.. ....._.....""'.'... PINE 2'-'1. I _. ;:: :~:.. ~--'- ;ffi :~It~~,~.=_.~...:~-s~ PINE . I C~~ .....--r.- I PINE 20'. : 3'-<1. PINE ;U;' ; 1'-10" 2B' '1'- 30' 6'- ...~ . - IS' 4'- 15' 2'- ,. ...,. IB' 3'- 1 , , 15' 3'. .,....,.'20' .. ......5;::0;' ..~~. == =!-i~jr- '.,. 22' i :3'-0. 20' i 6'-0" ~inliil 33' i b'-2" i 4'-1. 4'-B" .:2":io;- .- .,... 2'-5" 1'-0" b'-6. b'-5" b'-II" 2'-1" 2'-4" 3'-0' 5'-3" '1'-5" 0'-3. 5'-B. 1'-11" 2'-,~. O"-~. 2'- ,. 'I'. 1'-1 ,. 2'-~. 2'.;. 3'.'" 3'-4~ 2'-2" 1'-1. t;'-o" '1'-3" 2'-1" 2'-0" 10'-0" 2'-0" 2'-10. 2'-0. 2'-0. B'-4. 0"-4" I '1'-2" i 0'-3. ; 0'-3. 5'-1" 2'-0. 2'-0. 5'-4. 4'-0" 411" 5'-6. 5'-0. 4'-1' 5'-2. 4'-1. 01' 5, PINE 20" 5'-10., I ..~~:=.. =.. :~~~~~~:~::=f~: -::{~~~.:i:~;:~, _ ""04-' IN. CEDAR ,....,.....-.--....- ._- ..05. ;-.... .5,-PINE. T ....,-..,......- Ob .IN, CEDAR 10" .. ...::~.=:....~: _ OJ.:..,.. .... 5, PINE ' ...40' _ . .,;..__......_.... O'B IN, CEDAR.. ,.L Ie)' 0<1. '.. 5, PINE 4<5; ..10. IN, CEDAR ' ..-'i"O~ ....il 5, PINE ... :.... 40 ,.......i2., IN, CEDAR . .--"".12' ~:::::::;_.. 5, PINE , IN, CEDAR _ .i.5 . ...,..,_ 5, PINE ..., ~....., ..I~.... _...~N, CEDAR 11 5, PINE It; IN, CEDAR 1'1 IN, CEDAR ::~. IN, CEDAR -', IN. CEDAR 22 IN, CEDAR -~~~....__ IN. C.EDAR -- 24; 5, PINE .. ~r 1 IN5~::R m '21" ,;..... IN, CEDAR . -:it; IN, CEDAR ......29. IN, CEDAR IN, C.EDAR 5, PINE 5, PINE IN. CEDAR IN, CEDAR IN, CEDAR IN, CEDAR IN, CEDAR IN, CEDAR IN, CEDAR 5, PINE 5, PINE IN. CEDAR 5, PINE 5. PINE S, PINE 5, PINE IN, CEDAR 5, PINE :t~~ 5, PINE 5. PINE 5, PINE 5, PINE Callander Associates ~~ u.bon l:los\in Lnl FInq 1'lItc....d-"FInq ~FInq 311 Sewtndl /we.. Son _ CA!l44OI T 650.37S.1313 FfiS0.34.t.'!290 Ca.Uc..1J06 RevIIrlcna (> Copyright 2008 Callander Aasoclatoa l.4ndocopo ^"""""""', Inc. CJ Z z <( t= z ....J <( ...J a... a.. w C1J a: w Z w 0 a: I- i= 0 a: 0 <( > Z W ...J al 0 ::> 0 "E 0 m ~ Iii <( 0 a: 0 a: () Z W en "0 en c i= al 0 u: C1J a: c W al X a.. en Z -S :::l W ::> 0 -, en Date 01/15/08 Sc8e None Dmwn KD By CIlecIced Project No. 07.075 Cadd RIll ExCond1lona Shoet No. 1 I of 6 I KEYMAP /Hlc.KEY BLVD, // ;' HESmoRO""" BLVD~" ~. MEDIAN 2 MEOIAl'l:; ,\, ~..__- , MEDIAN I liKING DRIVE J\ ~ r\.JI o 10' 20' 40' FOR LEGEND SEE SHEET 1 Callander Associates ~- Ubon Dosign UncI flomns Pat end """""'" flomns &Mramonlzj flomns 311__ Son ,....", CA 9+401 T 6SO.37S.13 13 F 650,3.4.4.3290 Revlsloos r "Copyright 2008 Callander Associates ~ Arl:l>l1odura, In<. (!) Z z i= <( z ....J <( -1 C- o... w en a: w Z w a: 0 I- i= Cl a: 0 <( > Z W -1 as 0 :J "2 0 ~ 0 CO (ij <( 0 C!) a: 0 a: 0 l/) Z W '0 C/) c: i= as 0 It en a: c: W as X 0... (/) Z ..c: '5 W :J 0 -, (/) 0aIAl ScllIe Drawn By CMcked Project No. 07,075 Cadd FIe ExCondlIons 01/15/08 A1J Shown KD Sheet No. 2 of o w Z :J :x: o ~ KEYMAP FOR LEGEND SEE SHEET 1 BLVD, .(KING DRIVE 1\ ~ MEDIAN I MEDIAN 2 \Ii . Callander A<isodates ~- ~= Pat.ond_""""""a E'<Mrtrm:r1lloI""""""a 311_..... s..._CA!l<<01 T65O.31S..1313 F 650.3+4.3290 Cl.Lk.fol308 AevlIIona o Copyrlght 2008 Callander Associates I.&nd#eepo ~, Inc. (!J Z z <( t= z ...J <( ...J C- o... w CIJ a: w Z w 0 a: I- i= Cl a: 0 <( > Z W ...J al 0 :::> "E 0 ~ 0 m (ij <( 0 C) a: 0 a: () Z w (I) "0 C/') c: i= al 0 u: CIJ a: c: W al X a.. U) Z ..s W :::> :::I 0 J U) Date 01/15/08 ScllIo M Shown Drawn KD By Checked Project No. 07.075 Cadd FIll ExCondtlona s-t No. 3 of 6 KEYMAP FOR LEGEND SEE SHEET 1 /HIGKEY BLVD, /// ; ,I KINo DRIVE ,j: ~ MEDIAN I HE50SO"""," BL YO ~ \ MEDIAN 2 MEDIAN '3 ,\' rwI o 10' 20' 40' Callander Associates ~- u.bon o..v> lJnl~ Plld<ond_~ -~ 311 5<M:r1Ih..... s.. "'- CA 9<<01 T 6Sa315.1313 F 65Q3.4.4.3290 Ca.Uc..1308 RevloIcna (l Copyright 2008 Callander Assoclates ~ Arcl1l""'''.lnc. (!J Z z i= < z ...J <( -I a... a.. w (/J a: w Z w 0 a: I- i= 0 a: (5 <( > Z W -I <<l 0 ::::) "E 0 ~ 0 m (ij <( 0 a: 0 a: 0 Z w lJ) '0 C/) c:: i= <<l 0 U: (/J a: c:: W <<l X a.. (f) Z .s::::. '5 W ::::) 0 ...., (f) Date 01/15/08 SclIto All Shown Drawn KD By Checked ProJect No. 01.075 Cadd Aa ExCond1lona Shoot No. 4 of 8 KEYMAP r\.JI o 10' 20' 40' WE5WO=- BLVD ~\ MEDIAN 2 MEDIAN:; ,\ BLVD, I/KINO DRIVE J ~ MEDIAN I FOR LEGEND SEE SHEET 1 Callander Associates"> ~- U:ban o.q" ::t~"""'*'a ~ PIomIng 311__ San MoIoo, CA 94'10 1 T650.375..1313 F 650.3+4.3200 Ca.llc.+'308 RevlsIcns o Copyrlght 2008 ~rAr~t:. (!J Z z i= <( z -I <( ...J a... a.. w (IJ a: w Z w a: 0 t- i= 0 a: 0 <( > Z W ...J as 0 => "2 0 ~ 0 m tij <( 0 C) a: 0 a: () w It) Z "0 en c i= as 0 u: (IJ a: c W as X a.. ((J Z .c: '5 W => 0 ...., ((J - Dale Scllie Dravm By Checked Praject No. 07.075 Cadd Fie ExCondtlcns 01/15/08 As Shown KD s-t No. 5 of KEYMAP BLVD, ,(KING DRIVE }\ ~ MEDIAN I MEDIAN 2 r\.JI o 10' 20' 40' FOR LEGEND SEE SHEET 1 Callander Associates ~- Ulbon DmiIPl ::t~~ --~ 311__ s.. "'-'. CA 9<<01 T 650.37S.1313 F 65O.J.4.4.J29O Ca.lk..'306 RevlIlona o Copyright 2008 Calland.... Assoclates Lendecepo ~ Inc. (!J Z z i= <( z .....J <( ..J 0- 0... W (/J a: w Z w a: 0 I- i= 0 a: 0 <( > Z W ..J <<1 0 ::> "E 0 ~ () m tii <( 0 Cl a: 0 a: 0 w CI) Z '0 C/) c: i= <<1 0 U: (/J a: c: W <<1 X 0... (/J Z .t::. "5 W ::> 0 """) (/J Date 01/15/08 As Shown Sc8Ie Onlwn By Clleckod Project No. 07.075 Clldd FIll ExCondlIona KD SMeI No. 6 of CD ~ ~ EXISTINiS CONCRETE PAVINiS TO ..- L1iSHT POLE --0-- FENCE TO REMAIN REMAIN }:l: TRAFFIC SliSNAL . EXISTINiS COLORED CONCRETE G POLE PAVINiS TO REMAIN MONUMENT SIGN TO REMAIN EXISITNiS BRICK TO REMAIN TRAFFIC/REGULA TORY SliSNAGE I!iiiil STORN DRAIN INLET (Q) IRRliSATION BOX [gJ ELECTRICAL BOX 0 OTHER UTILITY DESCRIPTION I BOTANICAL NAME COHMON NAME SPACINiS - CONIFEROUS EYEReREEN #1 CHAMAECYPARIS LAHSONIANA GUPRESSOCYPARIS LEYLANDII THUJA PLlCATA CONIFEROUS EYEReREEN #2 SEQUOIA SEHPERVIRENS FALSE CYPRESS N,C,N, Y-<ESTERN RED CEDAR 30'-0" O,C, 30'-0" O,C, 30'-0" O,C, REDl^lOOD 30'-0" O,C" !".__.~.~^~"'---.- -BROADLEAF EYERiSREEN CUPANIOPSIS ANACARDIOIDES TRISTANIA CONFERTA EUGAL YPTUS FICIFOLlA AGGENT TREE ARBUTUS UNEDO MELALEUCA L1NARIIFOLlA METROSIDEROS EXCELSUS SHRUB/GROUNDCOVER CISTUS X PURPUREUS COLEONEMA 'SUNSET iSOLD' CEANOTHUS SPP, COPROSMA X KIRKII ESCALLONIA RUBRA LEPTOSPERMUM SCOPARIUM PITTOSPORUM TOBIRA 'l^lHEELER'S Dl^lARF' V ARIES VARIES VARIES VARIES VARIES VARIES VARIES CARROT l^lOOD BRISBANE BOX RED FLOY-<ERING GUM 30'-0" O,C, 30'-0" O,C, 30'-0" O,C, KEYMAP STAl^lBERRY TREE FLAXLEAF PAPERBARK NEl^l ZEALAND CHRISTMAS TREE 25'-0" O,C, 25'-0" O,C, 25'-0" O,C, BLVD, ,(KINiS DRIVE j MEDIAN 2 ROCKROSE BREATH OF HEAVEN l^lILD LILAC CREEPINiS COPROSMA ESCALLONIA NEl^l ZEALAND TEA TREE TOBIRA MEDIAN I Callander Associates lllndsalpeAzd1l1ooure Umon 0e0sn l1lndPlcnnl~ PIlII:llI1d_Plonnhg E'nvinJrrnernllPlcnnlna 311 Se.onlh ^"" 5<'ln Mateo, CA 94401 T650375.1313 F 650.344.3290 Cn.Uc.fl306 Ravislona o Copyright 2008 Callander Aaaoclatea landoctlpe Archltocturo, Inc. In ill Z :J :I: I::! ~ Cj z i= z <dC ...I I!l. W a: W w a: I- 0 a: <dC > W ...I (\1 :::> 0 "c: aJ ~ Iii <dC 0 a: ci a: 0 w Ul "0 UJ l::: (\1 0 u: a: l::: W (\1 ill. (f) Z .c: :J :::> 0 -, (f) Data Scale Drawn By Checl<ed Sheat No. 1 of KEYMAP FOR LEGEND SEE SHEET 1 BLVD, liKING DRIVE Jl MEDIAN I MEDIAN 2 Ii Callander Associates lJlndsa>pe Altlmectum UfhllnlJeslgn lJlndl'lonlin8 PeritMd_Plonnin8 ErM~ I'Ionnlng 311 Se\-'enthk.oe. San Mateo, CA 94401 T650.375.1313 F 650.3443290 Cc.Lk.+1306 <D Copyright 2008 Callander Associates LlUldDcaprJi ArCh/190MB, Inc. CJ z i= z ~ ...J Ill. W a: W w a: l- e a: ~ > W u.. ...J w :::::> lIS z '2 :J 0 i CD g (ij ~ () a: 0 a: 0 w <II '0 (IJ c:: lIS 0 u:: a: c:: W lIS Ill. en Z .r:: '5 :::'l 0 "'") en Date Sesle Drawn By Checked Project No, Cadd Fie Sheet No. 2 of Ci z ~ z <<( ...J 0- W or: w w a: I- IJJ 0 > a: :J: a: <<( w a > z 0 W :J :J: >- ....I ~ 0 ::l l"G cr: 0 'i:: cr: ~ <( CO iij <<( 0 a: 0' a: 0 W en '0 (J) l:: l"G 0 U: a: l:: w l"G 0- m Z -:E ::l ::l 0 """) 00 KEYMAP BLVD, ,r KING DRIVE j MEDIAN I MEDIAN 2 FOR LEGEND SEE SHEET 1 Callander Associates l.llndsaipe_ UrbimlJeslsn l.llndPlanring Pmlll1d""""","",PlMn"s ErM~PIanring 311 Se.<nlh ^"" """ """'" CA!l4401 T6S0J7S.1313 F650..3443290 Ca.Uc.+1306 Revislona <Cl Copyright 2008 Callander AaBoclateB LandnCl1pli Arch!tocturQ. Inc. Date 01115108 Scllle As Shown Drawn KD By Checked Sheet No. 3 of KEYMAP FOR LEGEND SEE SHEET 1 MEDIAN I ,(KING DRIVE j NEDIAN 2 Callander Associates l.andsc>pe- Urban~ lllnclPlm1rdng Potkllnc! ~ Plannmg ErniI1lM1t1llliPIMr/ng 311 5<Mlnlh /we. Son """'" CA 94401 T650.315.1313 F 650.3443290 Ca.Uc.fl300 Revislons <0 Copyright 2008 Callendar Associates LandGeapo Archllooture. Inc. CJ z i= z <( -II a.. W a:: w w r:c I- 0 a:: <( > W -II <1l :::> 'i:: 0 g 00 iU <( 0 r:c ci r:c 0 w III '0 (J) t: <1l 0 U: a: t: W <1l a.. en Z oS :::> ::J 0 """) en 01/15/08 As Shown KD 07.075 DraftPreim Sheet No. 4 01 'I 'I JUNIPERO SERRA BLVD. KIEYMAP BLVD, ",.ma="," BL VD ~ \ MEDIAN :2 1 MeDIAN:3 \ AVALON DR'VE) , ,(KING DRIVE j MEDIAN I LU > 0: o z o ..J ~ <( FOR LEGEND SEE SHEET 1 Callander Associates lor><lsc>pe_ U!ban DeOgn lond~ Pllri:ll<ld_PlannIng _PIonnIng 311 SlM:nth ^"'- San I&teo, CA 94401 T 650.375.1313 F 650.3443290 CAlk.+l300 Revisions o Copyright 2008 Callander Associates lnndllcnpo AtchllDctura, Inc. CJ z i= z < ..J iO.. W a: W w a: I- o a: < > W ...l tll :::> "E ~ g "iii < 0 a: 0 a: 0 w "~ C/) t:: tll o It a: t:: W tll iO.. (J) Z ~ :::> 0 .., (J) 01/15/08 As Shown KD Sheal No. 5 of Thuja plicata Melaleuca Tristania Sequoia Metrosideros January 15; 2008 Coleonema Arbutus unedo Cistus Ceanothus Escallonia Callander Associates Landscape Architecture, Inc. Cupressocyparis leylandii Chamaecyparis lawsoniana Coprosma X kirkii Cupaniopsis anacardioides Arbutus unedo Pittosporum tobira Leptospermum scoparium Eucalyptus ficifolia January 15; 2008 Callander Associates Landscape Architecture, Inc. <It Ceanothus spp. Existing Entry Sign Coprosma X kirkii Coleonema 'Sunset Gold' Existing concrete paving uary 15~ Callander Associates Landscape Architecture, Inc. Coleonema 'Sunset Gold' Ceanothus spp. 'Sunset Gold' 15~ Callander Associates Landscape Architecture, Inc. I iii B e \ Callander Associates "'dIapri~ K on nipero Serra Boulevard Tree Reforestat April 16,2008 City Council ;KINiS DRIVE HICKEY BLVD l^lE5TBOROUiSH BLVD.~ MEDIAN 2 MEDIAN 5 Junipero Serra Boulevard Tree Reforestati City Council April 16, 2008 c 9 Ii sa . ) Callander Associates I · IIpII ... --"-_ 1nc:. Junipero Serra Boulevard Tree Reforestation 16,2008 April City Council Callander Associates .........~Rs 'tnc. South San Junipero Serra Boulevard Tree Reforestation City Council April 16, 2008 Callander Associates lIII~~ Inc. Existing Conditi . Zone 1: Hickey to King, 150 trees Mature trees are predominantly Monterey . . I . Infill trees are Incense Cedar Junipero Serra Boulevard Tree Reforestation City Council Apri/16.2008 J pero Serra Boulevard Tree Reforestation - City Council April 16, 2008 nipero Serra Boulevard Tree Reforestation April 16, 2008 City Council unipero Serra Boulevard Tree Reforestation City Council Apri/16,2008 ti III I Existing Cond 67 trees y Monterey King to Westborough, trees are predominantl trees are ncense Cedar Zone 2: Mature n fi II . som e .. . Callander Associates lIIII~~ 1nc. Junipero Serra Boulevard Tree Reforestation Council 16,2008 nipero Serra Boulevard Tree Reforestation City Council April 16, 2008 Junipero Serra Boulevard Tree Reforestation City Council April 16,2008 unipero Serra Boulevard Tree Reforestation City Council April 16, 2008 ti III I xisting Cond trees 54 Westborough to Avalon, trees are Stone Pine trees are ncense Cedar Zone 3: Mature n fi II . . . Callander Associates lIIII~~ 1nc. Junipero Serra Boulevard Tree Reforestation Apri/16.2008 eforestation Tree J nipero Serra Bouleva City Council April Junipero Serra Boulevard Tree Reforestation City Council April 16,2008 unipero Serra Boulevard Tree Reforestati City Council Apri/16,2008 1 tio nipero Serra Boulevard Tree Reforesta April - 16,2008 City Council yea iod Junipero Serra Boulevard Tree Reforestation - - City April 16,2008 Council unipero Serra Boulevard Tree Reforestation City Council April 16, 2008 BLVD. ,(KINE> DRIVE l^IE5TSOROC\SH BL YO. ~ MEOIAN I MEt? \, H !~'" IAN .:;z ~\~l't ~ \ \\ Ir'~-,l~ ~ i'"" 1\ ~~~~~~~~nf~!li unipero Serra Boulevard Tree Reforestation City Council Apri/16,2008 BLVD. l^IE5TSOROC\SH 6L YO. ~ \ MEOIAN I MEt?IAN .:;z ~\~l't ~ \ lill~!II!!!1~!II!~~~\~~! Junipero Serra Boulevard Tree Reforestation City Council April 16,2008 BLVD. DRIVE l^IE5ll3OROl.\5H BL YO. ~ MEOIAN I MEt? \\ IAN .:;z ~\~l't ~ \ ~\ ~ i:i~n::>o:Ji:i.~o:.Ii:i.~~;,c.;;.,;,: ~"__"&__U'__""__._ ;;:}:;;~:;~~g:;:~t1' /~~~ Junipero Serra Boulevard Tree Reforestation City Council Apri/16,2008 BLVD. DRIVE l^IE5T6OROl1GH BL YO. ~ MEOIAN I MEt?IAN .:;z ~\~l't ~ \ \\ i;nU':;'=HI.:i~UI$~'i;;;; '''.''--''-'-_.&'--<'''"~~- ;;;~:;c:;':;~;;:~:;l;~8;:~W' Junipero Serra Boulevard Tree Reforestation City Council April 16,2008 I/H1CKEY BLYO. MEOIAN I ,(KINE> DRIVE l^IE5TSOROC\SH BL YO. ~ /1 ,Il MEt?IAN .:;z ~\~l't ~ ,,\\ - L~ 1" , ,~ ~ I( '-'">~'--~~_. I' ~i~~i~j~i pero Serra Bouleva Tree Reforestati - April 16, 2008 jllESTI9OROll6H BLVD. \ ..- \\\ ~\~l't ~ -\ MEt?IAN .:;z ,(KINE> DRIVE ~~ ~ I MEOIAN I rH1GKEY BLVD. /1/ .,-/ ! Tree Reforestati unipero Serra Bouleva Apri/16,2008 BLVD. ,(KINE> DRIVE jllESTI9OROll6H MEOIAN I ,Il MEt?IAN .:;z i- I ,. I ( , ----..=,::::; 1 :~~~~rii=ilm~mmmg~~r: Junipero Serra BOUlevard Tree Reforestation City Council April 16, 2008 BLVD. I'RIVE l^IE5ll3OROl.\5H BL YO. ~ MEOIAN I AN ~ ~\~l't ~ \ \\ fiarnlitia iUaSiiHJ;;r Junipero Serra Bouleva Tree Reforestatiol - Council Apri/16,2008 oUlevard Tree Reforestati April Council Boulevard Tree Reforestati April evard Tree Reforestati nipero Serra Boulevard Tree Reforestati City Council April 16, 2008