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Home My WebLink AboutCT 02-14; BRESSI RANCH RESIDENTIAL; INTERIM AS-GRADED REPORT OF ROUGH AND FINE; 2004-04-27INTERIM AS-GRADED REPORT OF ROUGH AND FINE GRADING, MODEL LOT COMPLEXES AND PHASE 1 LOTS, LOTS 1 THROUGH 13, 30 THROUGH 34, 55 THROUGH 63, 112, 127 THROUGH 143, 156 THROUGH 159, 169 THROUGH 172, 180 THROUGH 193, 263 THROUGH 272, 281 THROUGH 284, 374 THROUGH 377, 380 THROUGH 383, 404 THROUGH 411, 427 THROUGH 443, AND 448 THROUGH 452, PLANNING AREAS PA-6 THROUGH PA-10 AND PA-12, BRESSI RANCH, CARLSBAD TRACT NO. 00-06, CARLSBAD, CALIFORNIA Prepared for: LENNAR COMMUNITIES 1525 Faraday Avenue, Suite 300 Carlsbad, California 92008 Project No. 971009-014 April 27, 2004 Leighton and Associates, Inc. A LEIGHTON GROUP COMPANY Leighton and Associates, Inc. A LEIGHTON GROUP COMPANY April 27,2004 ProjectNo. 971009-014 To: Lennar Communities 1525 Faraday Avenue, Suite 300 Carlsbad, Califomia 92008 Attention: Ms. Kristine Zortman Subject: Interim As-Graded Report of Rough and Fine Grading, Model Lot Complexes and Phase 1 Lots, Lots 1 Through 13, 30 Through 34, 55 through 63, 112, 127 Through 143, 156 Through 159, 169 Through 172, 180 Through 193, 263 Through 272, 281 Through 284, 374 Through 377, 380 Through 383, 404 Through 411, 427 Through 443, and 448 Through 452, Planning Areas PA-6 through PA-10 and PA-12, Bressi Ranch, Carlsbad Tract No. 00-06, Carlsbad, Califomia In accordance with the request and authorization of representatives of Lennar Communities, we have performed geotechnical services during the rough and fine grading operations for the residential model lot complexes and Phase 1 production lots at the Bressi Ranch project (Carlsbad Tract No. 00-06), located in Carlsbad, Califomia. The model lot complexes and Phase 1 production lots include Lots 1 through 13, 30 through 34, 55 through 63, 112, 127 through 143, 156 tiirough 159, 169 tiirough 172, 180 through 193, 263 tiirough 272, 281 tiirough 284, 374 through 377, 380 through 383, 404 through 411, 427 tiirough 443, and 448 tiirough 452 of Planning Areas PA-6 through PA-10 and PA-12. The accompanying interim as-graded report summarizes our geotechnical observations, field and laboratory test results, and the geotechnical conditions encountered during the rough and fme grading operations for the subject lots. In addition, the accompanying report presents our geotechnical conclusions and recommendations conceming the post grading and constmction phases for the model lot complexes and Phase 1 production lots. The geotechnical information presented herein, along with a field density test summary and geotechnical map will be presented in the final as-grade reports that are currently being prepared for each of the residential planning areas. 3934 Murphy Canyon Road, Suite B205 • San Diego, CA 92123-4425 858.292.8030 • Fax 858.292.0771 • www.leightongeo.com 971009-014 The rough and fine grading operations for the model lot complexes and Phase 1 production lots of the Bressi Ranch project were performed in general accordance with tiie project geotechnical reports (Appendix A), geotechnical recommendations made during the grading operations, and tiie City of Carlsbad requirements. It is our professional opinion that the subject lots are suitable for the intended residential use provided the recommendations included herein and in the project geotechnical reports are incorporated into the design and constmction of the residential stmctures and associated improvements. As of the date of this report, the rough and fine grading operations for the model lot complexes and Phase 1 production lots are essentially complete. If you have any questions regarding our report, please contact this office. We appreciate this opportunity to be of service. Respectfully submitted, LEIGHTON AND ASSOCIATES, INC. WiUiam D. Olson, RCE 45283 Senior Project Engineer Randall X. Wagner J CEG 1612 Senior Associate Distribution: (4) Addressee (24) Greystone Homes, Attention: Mr. Keith Randhahn -2-Leighton 971009-014 TABLE OF CONTENTS Section Page LO INTRODUCnON 1 1.1 PROJECT DESCRIPnON 1 2.0 SUMMARY OF ROUGH AND FINE GRADING OPERATIONS 2 2.1 STTE PREPARATION AND REMOVALS 2 2.2 SUBDRAINS 2 2.3 BUTTRESS AND STABlijTY"FILL KEYS 3 2.4 FILL SLOPE KEYS 4 2.5 CUT/FILL TRANSmON CONDrnONS 4 2.6 OVEREXCAVATION OF BLOCKY WELL-CEMEIMTED SANTIAOT F^RI^ATION 4 2.7 OVEREXCAVATION OF HIGH TO VERY HIGH EXPANSIVE FORMATIONAL MATERIAL 5 2.8 PLACEMENT OF OVERSIZED MATERIAL 5 2.9 FILL PLACEMENT AND COMPACTION 5 2.10 FIELD DENSITY TESTING 6 2.11 LABORATORY TESTING 6 2.12 SETTLEMENT MONUMENT MONirORING OF DEEP FILLS 7 2.13 GRADED SLOPES 7 3.0 ENGINEERING GEOLOGIC SUMMARY 8 3.1 AS-GRADED GEOLOGIC CONDTnONS 8 3.2 GEOLOGIC UNITS 8 3.2.1 Undocumented Fill Soils (Map Symbol - Afu) 8 3.2.2 Topsoil 8 3.2.3 Alluvium/cioiluvium, Undifferentiated 9 3.2.4 Landslide Deposits 9 3.2.5 Santiago Formation 10 3.3 GEOLOGIC STRUCTURE 10 3.4 FAULTING AND SEISMIOTY 10 3.5 GROUNDWATER 11 3.6 EXPANSION AND SULFATE CONTENT fESTING OF REPRESENTATIVE FINISH GRADE SOILS 12 4.0 CONCLUSIONS 13 4.1 GENERAL 13 4.2 SUMMARY OF CONCLUSIONS 13 5.0 RECOMMENDATIONS 16 5.1 EARTHWORK 16 5.1.1 Site Preparation 16 5.1.2 Excavations 16 5.1.3 Fill Placement and Compaction 17 5.2 RESIDENTIAL FOUNDATION DESIGN CONSIDERATIONS , 17 5.2.1 Moisture Conditioning 20 Leighton 971009-014 TABLE OF CONTENTS (Continued) 5.2.2 Seismic Design Parameters 20 5.2.3 Foundation Setback 21 5.2.4 AnticipatedSettlement 22 5.3 LATERAL EARTH PRESSURES 22 5.3 LATERAL EARTH PRESSURES 22 5.4 FENCES AND FREESTANDING WALLS 24 5.5 CONCRETE 25 5.6 SLOPE MAINTENANCE GUIDELINES 26 5.7 CONTROL OF SURFACE WATER AND DRAINAGE 26 5.8 LANDSCAPING AND POST-CONSTRUCTION 27 5.9 CONSTRUCTION OBSERVATION AND TESTING 28 6.0 LIMITATIONS 29 TABLES TABLE 1 - LOT-BY-LOT SUMMARY OF AS-GRADED GEOTECHNICAL CONDITIONS - REAR OF TEXT TABLE 2 - POST-TENSIONED FOUNDATION DESIGN RECOMMENDATIONS - PAGE 18 TABLE 3 - PRESOAKING RECOMMENDATIONS BASED ON FINISH GRADE SOIL EXPANSION POTENTIAL • PAGE 20 TABLE 4 - MINIMUM FOUNDATION SETBACK FROM SLOPE FACES - PAGE 22 TABLE 5 - LATERAL EARTH PRESSURES - PAGE 23 APPENDICES APPENDIX A - REFERENCES APPENDIX B - LABORATORY TESTING PROCEDURES AND TEST RESULTS APPENDIX C - GENERAL EARTHWORK AND GRADING SPECIFICATIONS FOR ROUGH GRADING Leighton 971009-014 1.0 INTRODUCnON In accordance with the request and authorization of representatives of Lennar Communities, we have performed geotechnical services during the rough and fine grading operations for the residential model lot complexes and Phase 1 production lots at the Bressi Ranch project (Carlsbad Tract No. 00-06), located in Carlsbad, Califomia. The model lot complexes and Phase 1 production lots include Lots 1 through 13, 30 through 34, 55 through 63, 112, 127 through 143, 156 through 159, 169 through 172, 180 through 193, 263 through 272, 281 through 284, 374 through 377, 380 through 383, 404 through 411, 427 through 443, and 448 through 452 of Planning Areas PA-6 through PA-10 and PA-12. This interim as-graded report summarizes our geotechnical observations, field and laboratory test results, and the geotechnical conditions encountered during the rough and fine grading operations for the subject lots. In addition, this interim report presents our geotechnical conclusions and recommendations conceming the post grading and constmction phases for the model lot complexes and Phase 1 production lots. As of this date, the rough and fine grading operations are essentially complete. The geotechnical infonnation presented herein, along with a field density test summary and geotechnical map will be presented in the final as-grade reports, which are currently being prepared for each of the residential planning areas. 1.1 Proiect Description The Bressi Ranch development is located southeast of the intersection of El Camino Real and Palomar Airport Road in the central portion of tiie City of Carlsbad, Califomia. The site consists of an irregular-shaped piece of property bordered on the north by Palomar Airport Road, on tiie west by El Camino Real, on the soutiiwest and south by the La Costa - The Greens property, and by the Rancho Carrillo development and Melrose Drive to the east. The proposed development of the model lot complexes and Phase 1 production lots is anticipated to consist of the constmction of residential stractures, driveways, underground utility services, small retaining walls, concrete flatwork, landscaping, etc. We understand the residential stmctures will be up to two-stories in height and have slab-on-grade with wood-frame and stucco constmction. Leighton 971009-014 2.0 SUMMARY OF ROUGH AND FINE GRADING OPERATIONS The rough and fine grading operations for the model lot complexes and Phase 1 production lots were performed between June 2003 and April 2004. The grading operations were performed by Nelson and Belding while Leighton and Associates performed the geotechnical observation and testing services. Our field technicians were on site fiill-time during the grading operations while our field and project geologists were on site on a periodic basis. Grading of the site included: 1) the removal of potentially compressible undocumented fill, topsoil, colluvium, alluvium, landslide deposits, and weathered formational material; 2) the excavation of buttress keys; 3) the excavation of fill slope keys; 4) preparation of areas to receive fill; 5) the placement of subdrains in the canyon bottoms and buttress keys; 6) excavation of formational material; and 7) the placement of compacted fill soils. Up to approximately 40 feet of cut was excavated and a maximum of approximately 100 feet of fill was placed within the limits of the model lot complexes and Phase 1 production lots. Table 1 (presented at the rear of text) summarizes the type of lot (cut, fill, cut/fill ti-ansition, dense rock or expansive material overexcavation, etc.), expansion index, approximate maximum fill thickness, and differential fill thickness on the lots graded during the rough and fine grading operations. 2.1 Site Preparation and Removals Prior to grading, the areas of the proposed development were stripped of surface vegetation and debris and these materials were disposed of away from the site. Removals of unsuitable and potentially compressible soils (including undocumented fill, topsoil, colluvium, alluvium, landslide deposits, and weathered formational material) were made to competent material. The removals of potentially compressible material were perfomied in accordance with the recommendations of the project geotechnical reports (Appendix A) and geotechnical recommendations made during the course of grading. After the removals were made, the removal areas flatter than 5:1 (horizontal to vertical) were scarified a minimum of 12 inches, moisture-conditioned as needed to obtain a near- optimum moisture content and compacted to a minimum 90 percent relative compaction, as determined by American Society for Testing and Materials (ASTM) Test Method D1557. The steeper natural hillsides were benched into competent material as fill was placed. 2.2 Subdrains Canyon subdrains were placed under the observation of a representative of Leighton and Associates during the rough grading operations for the Bressi Ranch project. After tiie potentially compressible material in the canyons were removed to competent material or Leighton 971009-014 when compacted fill was placed over competent material to obtain flow to a suitable outiet location, a subdrain was installed along the canyon bottom. The canyon subdrains consist of a 6-inch diameter perforated pipe surrounded by a minimum of 9-cubic feet (per linear foot) of cmshed 3/4-inch gravel wrapped in Mirafi HON geofabric. In addition to the canyon subdrains, subdrains were also installed along the bottom of the butfress key and stability fill keys. The buttress and stability fill subdrains consisted of a 4- inch diameter perforated pipe surrounded by a minimum of 3-cubic feet (per linear foot) of clean 3/4-inch gravel wrapped in Mirafi 140N filter fabric. Where applicable, an additional subdrain was also installed along the buttress backcut at an approximate 30-foot vertical interval above the key bottom. The subdrains were placed with a minimum 1-percent fall (2-percent or greater where possible) to a suitable outlet location. The location of the canyon subdrains placed during the rough grading operations for the project were surveyed by the project civil engineer. The subdrain locations will be presented on the as-graded geotechnical map for each of the planning areas. 2.3 Buttress and Stabilitv Fill Kevs Based on geotechnical analysis performed during the preliminary and supplemental geotechnical investigations of the site (Appendix A), butfress and stability fills were recommended to improve the gross stability of the existing hillsides and proposed graded areas in areas of existing landslides and/or other adverse geologic conditions. Based on our geotechnical analysis, a butfress was excavated on Lots 427 through 433, 442, and 443 on the north side ofPlanning Area PA-12. The other landslides encountered within the proposed grading limits of Planning Areas PA-6 through PA-10 and PA-12 were removed to competent landslide material or competent formational material during the rough and fine grading operations. The buttress key on the north side ofPlanning Pnea. PA-12 ranged from approximately 50 to 60 feet wide at an approximate depth of 5 feet below the clayseam/potential failure surface (i.e. at an approximate elevation of 179 to 181 feet mean sea level [msl]). The buttress key bottom was also excavated with a minimum 2 percent inclination into the slope. The butfresses front cut and backcuts were excavated at overall slope inclinations of 1:1 (horizontal to vertical) or flatter. The approximate location of the buttress will be presented on the as-graded geotechnical map of the final as-grade report for Planning Area PA-12. Based on our geotechnical analysis, two stability keys were excavated adjacent to the model lot complexes and Phase 1 production lots. One of the stability fill keys was constmcted on the north side of Lots 443 and 518 in Planning Area PA-12 while the other stability fill was constmcted on the northeast side of Lots 276 through 280 in Planning Area PA-9. Leighton 971009-014 The stability fills were constincted to stabilize the exposed claystone/siltstone and/or adverse geologic conditions within the Santiago Formation. The stability fill keys were excavated a minimum of 5 feet below the toe-of-slope, a minimum of 15 feet to 20 feet wide, with the key bottom angled at least 2 percent into-the-slope. The stability fill front cuts were excavated near vertical while the backcuts were excavated at an approximate 1:1 or less (horizontal to vertical) inclination. The approximate location ofthe stability fills will be presented on the as-graded geotechnical maps of the final as-grade reports for Planning Areas PA-9 and PA-12. 2.4 Fill Slooe Kevs Prior to the placement of fill slopes that were placed above natural and/or cut areas on the site, a fill slope key was constmcted. The fill slope keys were excavated at least 2 feet into competent soil along the toe-of-slope and constmcted approximately 15 feet wide witii the key bottom angled a minimum of 2 percent into-the-slope. 2.5 Cut/Fill Transition Conditions The cut portion of lots that exposed the cut/fill transition within the relatively level building pad was overexcavated a minimum of 3 feet below finish pad grade. Overexcavation of the building pad was performed to mitigate the transitional condition and related adverse effects of differential settlement that can resuh due to this underlying condition. The limits of the overexcavations were made at least 5 feet outside the anticipated building limits (or building footprint). To reduce the potential of a perched ground water condition within the transition lots, the pads were overexcavated with a 1- foot fall in the overexcavation bottom toward the fill. Lots that were overexcavated due to a cut/fill transition condition included Lots 7, 8, 136, 156, 171, 187, 375 through 377, 381, and 382. 2.6 Overexcavation of Blockv Well-Cemented Santiaao Formation During the rough and fine grading of the Bressi Ranch project, geologic mapping indicated that a number of lots contained well-cemented sandstone beds (or concretion layers) and very dense or hard Santiago Formation at or near finish grade. Due to the potential difficulties in excavating the well-cemented layers and very dense or hard Santiago Formation, recommendations were made during the coarse of the grading operations to overexcavate and replace the material with compacted fill. The lots exposing the well- cemented sandstone and very dense or hard Santiago Formation were overexcavated to a minimum depth of 3 feet at the rear of the lot and a minimum depth of 4 feet at the front of the lot (i.e. with a 1-foot fall in the overexcavation bottom toward the sfreet) in order to -4- Leighton 971009-014 reduce the potential of a perched groundwater condition on the lots. Lots where overexcavation was performed due to the well-cemented sandstone and very dense or hard Santiago Fonnation included Lots 9 through 13, 127 through 135, 137 tiirough 143, 169, 170, 180 through 186, 188 through 193, 263, 264, 268 through 272, 380, 383, and 407 through 411. 2.7 Overexcavation of High to Verv High Exoansive Formational Material Due to tiie expansive nature of some of the siltstones and claystones present on the site, geologic observation and mapping was performed during the grading operations to determine if high to very highly expansive formational materials were located at finish grade on the lots. Cut lots where expansive formational material was identified at finish grade were undercut until the expansive material was removed or to a minimum depth of approximately 4 feet. The lots exposing the expansive formational materials were also overexcavated with a 1-foot fall in the undercut bottom towards to the street (in order to reduce the potential of perched ground water on the lots). Upon completion of the rough and fine grading, expansion potential testing was performed on tiie lots to determine the expansion potential of the finish grade soils on the lots. Lots that were undercut due to expansive formational materials include Lots 281 through 284. 2.8 Placement of Oversized Material During the rough and fine grading operations of the Bressi Ranch project, the well cemented or concretionary beds that where encountered witiiin the Santiago Formation typically resulted in the generation of rock fragments ranging from less than 6 inches to greater than 4 feet in maximum dimension. In order to minimize difficult excavation of fiiture utility trenches or foundations excavations, recommendations were made during the rough grading operations to place the oversized rock (generally defined as greater than 8 inches in diameter) below a depth of 5 to 10 feet below the finish grade elevation of the fill areas. While the contractor made their best effort to minimize the rock within tiie upper 5 to 10 feet of the finish grade surface, some oversized rock should be anticipated. In addition, cemented or concretionary beds may be encountered below shallow fills on the site during future grading and utility trench excavation that may result in the generation of additional oversized rock. 2.9 FiH Placement and Compaction After the completion of the remedial grading removals, processing of the excavated areas, and/or installation of the subdrains, on-site soil was placed as compacted fill. The on-site soil was generally spread in 4- to 8-inch loose lifts; moisture conditioned as needed to attain -5- Leighton 971009-014 a near-optimum moisture content, and compacted. Field density test results performed during the grading operations indicated the fill soils were compacted to at least 90 percent of the maximum dry density in accordance with ASTM Test Method D1557. To mitigate post-constmction settlement, the lower portions of the deep fill areas (i.e. areas where the fill soils are generally deeper than approximately 40 feet below the proposed finish grade elevations of the site) were placed in accordance with the geotechnical recommendations relative to deep fills (Leighton, 2003d). In general, the fill soils below a depth of approximately 40 from the sheet-graded pad elevations were placed and compacted to a minimum relative compaction of 95 percent relative compaction. Deep fill areas are present beneath Lots 1 through 4, 55 through 59, 427 through 434, 440 through 443 and 448 through 452. Compaction of the fill soils was achieved by use of heavy-duty constmction equipment (including mbber-tire compactors and 637, 651, and 657 scrapers). Areas of fill in which field density tests indicated compactions less than the recommended relative compaction or where the soils exhibited nonuniformity or had field moisture contents less than approximately 1 to 2 percent below the laboratory optimum moisture content, were reworked. The reworked areas were recompacted, and re-tested until the reconimended minimum 90 or 95 percent relative compaction and near-optimum moisture content was achieved. Table 1 (presented at the rear of text) summarizes the type of lot (cut, fill, cut/fill transition, rock or expansive material overexcavation, etc.), expansion index, approximate maximum fill tiiickness, and differential fill thickness on the lots graded during the rough and fine grading operations. The differential fill thickness values presented on Table 1 and utilized in the design recommendations of this report are the difference between the minimum and maximum ftll thicknesses across the relatively level building pad on each of the lots as shown on the grading plans. 2.10 Field Densitv Testing Field density testing and observations were performed using the Nuclear-Gauge Method (ASTM Test Metiiods D2922 and D3017). The field density testing was performed in general accordance with the applicable ASTM Standards, the cunent standard of care in the industry, and the precision of the testing method itself Variations in relative compaction should be expected from the documented results. The approximate test locations and test results will be provided in the final as-grade report for each of the planning areas. 2.11 Laboratory Testing Laboratory maximum dry density tests of representative on-site soils were performed in -6- Leighton 971009-014 general accordance with ASTM Test Method D1557. Expansion potential and soluble sulfate content tests of representative finish grade soils were also performed in accordance with UBC 18-2 and standard geochemical methods, respectively. The test resuhs are presented in Appendix B, on Table 1, and discussed in Section 3.6. 2.12 Settlement Monument Monitoring of Deep Fills Upon completion ofthe rough and fine grading operations in deep fill areas (i.e. fill areas generally greater than approximately 40 feet in depth) witiiin the Bressi Ranch project, settlement monuments were placed. The settlement monuments were initially surveyed following the installation and on a periodic basis (generally on a weekly basis). Preliminary review of the settlement readings indicates tiiat most of the anticipated primary settlement has occuned. However, we recommend that the settlement monuments continue to be surveyed and the results reviewed by Leighton. With the exception of Lots 448 through 452 in Planning Area PA-12, the stmctures on the lots within the deep fill areas (i.e. Lots 1 through 4 and 55 through 59 in Planning Area PA-6 and Lots 427 through 434 and 440 through 443 in Planning Area PA-12) should not be started until our settlement analysis indicates the primary settlement is essentially completed. The residential stmctures of the model lots and Phase 1 production lots in the deep fill areas should be designed in accordance with the recommendations presented in Section 5.2. 2.13 Graded Slopes Graded and natural slopes within tiie developed portion of the fract are considered grossly and surficially stable from a geotechnical standpoint. Manufactured cut and fill slopes within the fract were surveyed by the civil engineer are understood to have been constmcted with slope inclinations of 2:1 (horizontal to vertical) or flatter. -7- Leighton 971009-014 •3.0 ENGINEERING GEOLOGIC SUMMARY 3.1 As-Graded Geologic Conditions The geologic or geotechnical conditions encountered during the rough and fine grading of the site were essentially as anticipated. A comprehensive summary of the geologic conditions (including geologic units, geologic stmcture, and faulting) is presented below. 3.2 Geologic Units The geologic units encountered during tiie rough and fine grading operations consisted of undocumented fill, topsoil, colluvium, alluvium, landslide deposits, and the Santiago Formation. Due to the potentially compressible nature of the undocumented fill, topsoil, colluvium, alluvium, landslide deposits, and weathered formational material, these soils were removed to competent material during the rough and fine grading operations. The as- graded geologic units encoimtered during the grading operations are discussed (youngest to oldest) below. 3.2.1 Undocumented Fill Soils Undocumented ftll soils were observed in a number of places on the site. The undocumented fills were generally associated with the grading of the onsite dirt roads, retention basins, and prior farming activities. These fill soils ranged from 1 to 10 feet in depth, and generally consist of dry to damp, loose or soft sand and clay. All existing undocumented fill located within the limits of grading were removed to competent formational material. 3.2.2 Topsoll A relatively thin veneer of topsoil was removed from the majority of tiie site. The topsoil, as encountered, consisted predominantly of a brown, damp to moist, loose, sandy clay and minor clayey to silty sand. The topsoil was generally massive, porous, and contained scattered roots and organics. Topsoil removal thicknesses were on the order of 1 to 4 feet thick. During the grading operations, the topsoil was observed to have been removed within the limits of grading. Leighton 971009-014 3.2.3 Alluvium/Colluvium. Undifferentiated Alluvium and colluvium was encountered during the rough grading operations in the tributary canyons and on the lower portion of the hillsides on the site. As encountered, the alluvium and colluvium consisted of dark brown, moist, loose to stiff, clayey sand, sandy clay, and silty sand. Where encountered, the alluvium and colluvium was removed to competent material. Up to approximately 20 feet of alluvium and colluvium was removed during the rough and fme grading operations. 3.2.4 Landslide Deposits Several ancient landslides were encountered in Planning Areas PA-6, PA-10, and PA-12. The landslide deposits generally consisted of moderately loose to dense materials derived from the Santiago Formation. The landslide deposits included graben in-fill material, relatively undisturbed blocks of formational material (within the central portion of the landslide mass), and disturbed/weathered material and buried topsoil, colluvium and/or alluvium (around the side flanks and the toe of the landslides). The landslide deposits generally consisted of moderately to heavily fractured silty sand and sandy clay. The landslide basal mpture surfaces generally consisted of a remolded clay seam. Geologic mapping during the buttress excavation and landslide removals indicated the landslides failed on slightly undulatory, very shallow dipping (2 to 5 degrees out-of-slope inclinations) planner and polished surfaces. Up to approximately 20 feet of the compressible landslide deposits were removed during the rough and fine grading operations. Due to their compressible nature and potential instability, remedial measures were performed on the landslides encountered during the rough grading operations within the graded limits of the site. The remedial grading measures included the removal of the loose and compressible landslide material of the larger landslides; complete removal of minor landslides; and the constmction of buttress fills to stabilize the landslides. In general, the buttress keys were excavated a minimum of 5 feet below the landslide mpture surface. The approximate limits of the landslide deposits encountered during the grading operations will be presented on the as-graded geotechnical map in the final as- graded report for each of the planning areas. -9- Leighton 971009-014 3.2.5 Santiago Formation The Tertiary-aged Santiago Formation, as encountered during the rough and fine grading operations, consisted primarily of massively bedded sandstones and claystones/siltstones. The sandstones generally consisted of orange-brown (iron- oxide staining) to light brown, damp to moist, dense to very dense, silty very fme to medium grained sandstone. The siltstones and claystones were generally olive-green to gray (unweathered), damp to moist, stiff to hard, moderately weathered, and occasionally fractured and moderately sheared. Several well-cemented fossiliferous sandstone beds were encountered during the rough and fine grading operations. 3.3 Geologic Structure The general stmcture of the formational material appears to be near horizontal. Based on our geologic mapping during the rough and fine grading operations, bedding within the Santiago Formation generally exhibited somewhat variable bedding with strikes ranging from northwest to northeast and dips typically 2 to 9 degrees to the southeast and northwest. Locally, cross bedding was observed with dips steeper than 15 degrees. Jointing on-site was observed to be very variable, but predominantly trended subparallel to the existing slopes. Jointing dips were found to be generally moderately to steeply dipping. Jointing was mainly encountered in the upper portion of the bedrock becoming less pronounced with depth. Randomly oriented shears were encountered in the Santiago Formation claystone and siltstone units. Numerous wide, diffuse zones of shearing, as well as more well-defined zones, were encountered in the bedrock, and are thought to be the result of regional tectonic shearing of the relatively stiff and unyielding siltstone and claystone. 3.4 Faulting and Seismicity Our discussion of faults on the site is prefaced with a discussion of Califomia legislation and state policies conceming the classification and land-use criteria associated with faults. By definition of the Califomia Mining and Geology Board, an active fault is a fault that has had surface displacement within Holocene time (about the last 11,000 years). The State Geologist has defined a potentiallv active fault as any fault considered to have been active during Quatemary time (last 1,600,000 years) but that has not been proven to be active or inactive. This definition is used in delineating Fault-Rupture Hazard Zones as mandated by the Alquist-Priolo Earthquake Fault Zoning Act of 1972 and as most recently revised in 1997. The intent of this act is to assure that unwise urban development does not occtfr across the traces of active faults. Based on our review of the Fault-Rupture Hazard Zones, -10- Leighton 971009-014 the site is not located within any Fault-Rupture Hazard Zone as created by the Alquist- Priolo Act (Hart, 1997). San Diego, like the rest of southem Califomia, is seismically active as a result of being located near the active margin between the North American and Pacific tectonic plates. The principal source of seismic activity is movement along the northwest-trending regional fault zones such as the San Andreas, San Jacinto and Elsinore Faults Zones, as well as along less active faults such as the Rose Canyon Fault Zone. As indicated in tiie Supplemental Geotechnical Report for the Bressi Ranch project (Leighton, 2001), there are no known major or active faults on or in the immediate vicinity of the site. Evidence of active faulting was not encountered during the rough and fine grading operations. However, several minor inactive faults were encountered but are not considered a constraint to development. The nearest known active fault is tiie Rose Canyon Fault Zone, which is considered a Type B Seismic Source based on the 1997 Uniform Building Code (UBC), is located approximately 7.0 miles (11.2 kilometers) west of the site. Because ofthe lack of knowii active faults on the site, the potential for surface mpture at the site is considered low. Shallow ground mpture due to shaking from distant seismic events is not considered a significant hazard, although it is a possibility at any site. Liquefaction and dynamic settlement of soils can be caused by strong vibratory motion due to earthquakes. Both research and historical data indicate that loose, saturated, granular soils are susceptible to liquefaction and dynamic settlement. Liquefaction is typified by a loss of shear strength in the affected soil layer, thereby causing the soil to act as a viscous liquid. This effect may be manifested by excessive settlements and sand boils at the ground surface. The fill and formational materials underlying the site are not considered liquefiable due to their fine-grained nature, dense physical characteristics and/or unsaturated condition. 3.5 Ground Water Perched ground water was encountered during the rough grading operations in the alluvial soils within the main drainages on the site. Since the alluvial soils were completely removed during the rough grading operations and subdrains installed in the canyon bottoms, groundwater conditions should not be a consfraint to development. Based on the site- specific as-graded geotechnical conditions and our geotechnical analysis during site grading, the geotechnical consultant has analyzed conditions that may result in ground water seepage and appropriate recommendations, if necessary, have been made. However, unanticipated seepage or ground water conditions may occur after the completion of grading and establishment of site irrigation and landscaping. If these conditions should occur, steps to mitigate the seepage should be made on a case-by-case basis. -11- Leighton 971009-014 3.6 Expansion and Sulfate Content Testing of Representative Finish Grade Soils Expansion potential and soluble sulfate content tests were performed on representative finish grade soils of the residential model lots and Phase 1 production lots. The test resuhs indicate the representative finish grade soils have a very low to high expansion potential and have a negligible to severe soluble sulfate content per the UBC criteria (ICBO, 1997). The laboratory test results and procedures are presented in Appendix B and on Table 1. -12- Leighton 971009-014 4.0 CONCLUSIONS 4.1 General The rough and fine grading operations for the residential model lot complexes and Phase 1 production lots of the Bressi Ranch project were performed in general accordance with the project geotechnical reports (Appendix A), geotechnical recommendations made during grading, and the City of Carlsbad requirements. It is our professional opinion that the subject lots are suitable for the intended residential use provided the recommendations included herein and in the project geotechnical report are incorporated into the design and constmction of the residential stmctures and associated improvements. The following is a summary of our conclusions conceming the rough and fine grading of the site. 4.2 Summary of Conclusions • Geotechnical conditions encountered during rough and fine grading were generally as anticipated. • Site preparation and removals were geotechnically observed. • The geologic units encountered during the rough and fine grading of the site consisted of undocumented fill soils, topsoil, colluvium, alluvium, landslide deposits, and the Santiago Formation. • Unsuitable undocumented fill soils, topsoil, colluvium, alluvium, landslide deposits, and weathered formational material were removed to competent material within the limits of grading. • Subdrains were placed in the canyon bottoms and .along the heel of the butfress and stability fill keys during the rough and fine grading operations. • Buttress and stability fills were constmcted to improve the gross stability of the landslides and cut slopes exposing fractured and blocky formational material and/or adverse geologic conditions on the site. The buttress and stability fill keys were excavated in accordance with the project geotechnical recommendations. • Fill slopes located above natural ground or cut areas were constmcted with a fill slope key. All keys were excavated to a minimum 15 feet wide, at least 2 feet into competent material along the toe-of-slope with the key inclined 2 percent into the slope. -13- Leighton 971009-014 • The cut'fill fransition conditions on Lots 7, 8,136, 156, 171, 187, 375 through 377, 381, and 382 were geotechnically mitigated by the overexcavation and recompaction of approximately the upper 3 to 4 feet of the lot. • The well-cemented sandstone beds and very dense or hard Santiago Formation on Lots 9 through 13, 127 through 135, 137 through 143, 169, 170, 180 through 186, 188 through 193, 263, 264, 268 through 272, 380, 383, and 407 through 411 was overexcavated to a minimum depth of 3 feet and replaced with compacted fill. • Cut lots where expansive formational material was identified at finish grade were undercut until the expansive material was removed or to a minimum depth of approximately 4 feet. Lots that were undercut due to expansive formational materials include Lots 281 through 284. Oversized rock generated during the grading operations was placed at least 5 feet below finish grade elevations. Fill soils were derived from onsite soils. The maximum fill depth within the limits of the model lots and Phase 1 production lots ranged from 4 to approximately 100 feet in depth. Field density testing indicated that the fill soils were placed and compacted to at least 90 percent relative compaction (based on ASTM Test Method D1557) and near- optimum moisture content in accordance vsdth the recommendations of Leighton and Associates and the requirements of the City of Carlsbad. To mitigate post-constmction settlement, deep fills (i.e. areas where the fill soils are generally deeper than approximately 40 feet below the finish grade elevations of the site) were placed at a minimum 95 percent relative compaction. Deep fill areas are present beneath Lots 1 through 4, 55 through 59, 427 through 434, 440 through 443, and 448 through 452. Ground water seepage conditions were encountered during the mass grading operations of the Bressi Ranch project. No evidence of active faulting was encountered during the grading operations within the limits of model lot complexes or the Phase 1 production lots. However, minor inactive faulting was encountered but should not be a constraint to development. Due to the dense nature of the onsite soils, it is our professional opinion that the liquefaction hazard at the site is considered low. -14- Leighton 971009-014 Settlement monitoring of the deep fills indicates that most of the primary settlement of the deep fills has already occuned. With the exception of Lots 448 through 452 in Planning Area PA-12, the stmctures on the lots within the deep fill areas (i.e. Lots 1 through 4 and 55 through 59 in Planning Area PA-6 and Lots 427 through 434 and 440 through 443 in Planning Area PA-12) should not be started until our settiement analysis indicates the primary settlement is essentially completed. The expansion potential of representative finish grade soils of the lots was tested and found to have a very low to high expansion potential. The laboratory test results are presented in Appendix B and on Table 1. The potential for soluble sulfate attack (on Type I/II cement) of the finish grade soils was tested and possess negligible to severe soluble sulfate contents. The laboratory test results are presented in Appendix B. It is our opinion that the slopes of the development possess a static factor of safety of at least 1.5 to resist deep-seated failure (under normal irrigation/precipitation pattems), provided the recommendations in the project geotechnical reports are incorporated into the post-grading, constmction and post-constmction phases of site development. -15- Leighton 971009-014 5.0 RECOMMENDATIONS 5.1 Earthwork We anticipate that fiature earthwork at the site will consist of site preparation, fine grading, utility trench excavation and backfili, and retaining wall backfili and compaction. We recommend that the earthwork on site be performed in accordance with the following recommendations, the General Earthwork and Grading Specifications for Rough Grading included in Appendix C, and the City of Carlsbad grading requirements. In case of conflict, the following recommendations shall supersede those in Appendix C. The contract between the developer and earthwork contractor should be worded such that it is the responsibility of the confractor to place the fill properly and in accordance with the recommendations of this report and the specifications in Appendix C, notwithstanding the testing and observation of the geotechnical consultant. 5.1.1 Site Preparation During fiiture grading, the areas to receive stmctural fill or engineered stractures should be cleared of surface obstmctions, potentially compressible material (such as desiccated fill soils or weathered formational material), and stripped of vegetation. Vegetation and debris should be removed and properly disposed of off site. Holes resulting from removal of buried obstractions that extend below finish site grades should be replaced with suitable compacted fill material. Areas to receive fill and/or other surface improvements should be scarified to a minimum depth of 12 inches, brought to moisture contents of at least 2-percent over the optimum moisture content, and recompacted to at least 90 percent relative compaction (based on ASTM Test Method D1557). If the length of time between the completion of grading and the constmction of the lots is longer than six months, we recommend that the building pads be evaluated by the geotechnical consultant and, if needed, the finish grade soils on the building pads should be scarified a minimum of 12 inches, moisture-conditioned to 2-percent above the optimum moisture-content and recompacted to a minimum 90 percent relative compaction (based on ASTM Test Method D1557). 5.1.2 Excavations Excavations of the on-site materials may generally be accomplished with conventional heavy-duty earthwork equipment. It is not anticipated that blasting will be required or that significant quantities of oversized rock (i.e. rock with maximum dimensions greater than 8 inches) will be generated during future grading. However, localized cemented zones within the shallow fill and cut areas and oversized rock -16- Leighton 971009-014 placed within the compacted fill may be encountered that may require heavy ripping or special grading measures. If oversized rock is encountered, it should be placed in accordance with the recommendations presented in Appendix C, hauled offsite, or placed in non-stmctural or landscape areas. Due to the relatively dense characteristics of the on-site soils, temporary excavations such as utility trenches in the on-site soils should remain stable for the period required to constmct the utility, provided they are constmcted and monitored in accordance with OSHA requirements. 5.1.3 Fill Placement and Compaction The on-site soils are generally suitable for re-use as compacted fill provided they are free or organic material, debris, and rock fragments larger than 8 inches in maximum dimension. We do not recommend that high or very high expansive soils be utilized as retaining wall backflll. In general, all fill soils should be brought to 2-percent over the optimum moisture content and compacted in uniform lifts to at least 90 percent relative compaction based on the laboratory maximum dry density (ASTM Test Method D1557). The optimum lift thickness required to produce a uniformly compacted fill will depend on the type and size of compaction equipment used. In general, fill should be placed in lifts not exceeding 8 inches in compacted thickness. Placement and compaction of fill should be performed in general accordance with Appendix C, the current City of Carlsbad grading ordinances, sound constmction practices, and the geotechnical recommendations presented herein. 5.2 Residential Foundation Design Considerations The proposed foundations and slabs of the proposed stmctures should be designed in accordance with stractural considerations and recommendations presented herein. Since soils ranging from very low to high expansion potential are present, as well as building pads having a significant fill differential thickness (considered to be a fill thickness differential of 20 feet or more) and/or within deep fill areas (i.e. areas underlain by approximately 40 feet or more of fill), we recommend the use of post-tensioned slab and foundation systems. We recommend that the post-tensioned slabs be designed in accordance with the following design parameters presented on Table 2 and the criteria of the cunent edition of the Uniform Building Code/Califomia Building Code. The post-tensioned foundations should be designed in accordance with building pad specific expansion potential, significant deep fill or fill differential and anticipated long-term differential settlement (if applicable) as indicated in Section 5.2.4. -17- Leighton 971009-014 Table 2 Post-Tensioned Foundation Design Recommendations Lot Numbers Design Criteria Lots 5-9, I so- ls 1,263,264, 267- 272,281-284, 374-377, 380-383, 404-410, and 435- 439 Lots 10-13,31- 34,112,127-131, 137-143, 156-159, 169-172, and 182- 193 Lots 132-136 and 411 Lots 1-4,30,55- 63, 265-266,427- 434,440-443, and 448-452 Lot Numbers Design Criteria Minimal Fill Thickness or Fill Differential and Very Low to Low Expansion Potential (Expansion Index less than 50) Minimal Fill Thickness or Fill Differential and Medium Expansion Potential (Expansion Index between 51 and 90) Minimal Fill Thickness or Fill Differential and High Expansion Potential (Expansion Index between 91 and 120) Significant Fill Thickness and/or Fill Differential with Low to High Expansion Potential (Expansion Index between 21 and 120) Edge Moisture Variation, Cm Center Lift: 5.5 feet 5.5 feet 5.5 feet 5.5 feet Edge Moisture Variation, Cm Edge Lift: 2.5 feet 3.0 feet 4.5 feet 5.5 feet Differential Swell, ym Center Lift: 1.0 inches 2.0 inches 3.0 inches 4.0 inches Differential Swell, ym Edge Lift: 0.4 inches 0.8 inches 1.2 inches 1.5 inches Angular Distortion Value: 1/800 1/600 1/600 1/500 Allowable Bearing Capacity: 2,000 psf Perimeter Footing Depth: 12 inches 18 inches 24 inches 30 inches -18- Leighton 971009-014 Long-term differential settlement is anticipated to occur when the fill soils become wetted by inigation and/or precipitation years after the completion of constraction. Angular distortion values, which are the ratio of the estimated differential settlement to the horizontal distance over which the settlement is likely to occur, are provided on Table 2. The estimated angular distortion value assumes 1) a relatively uniform fill settlement across the stmcture; and 2) the actual settlement will not likely vary more than one-quarter of the stated angular distortion at any one point. The angular distortion values may be fiirther evaluated based on a review of the precise grading plans. The post-tensioned foundations and slabs should be designed in accordance with stmctural considerations. Continuous footings with a minimum width of 12 inches and a minimum depth of 12, 18, 24, or 30 inches below adjacent grade (as indicated on Table 2) may be designed for a maximum allowable bearing pressure of 2,000 pounds per square foot if founded into competent formational soils or properly compacted fill soils. The allowable bearing capacity may be increased by one-tiiird for short-term loading such as wind or seismic forces. Where the foundation is within 4 feet (horizontally) of adjacent drainage swales, the adjacent footing should be embedded a minimum depth of 12 inches below the swale flowline. The post-tension slabs should be a minimum of 5 inches thick. The slabs should be underlain by a minimum of 2 inches of clean sand (sand equivalent greater than 30) that is in tum underlain by plastic sheeting (10-mil) and an additional 2 inches of clean sand. The plastic sheeting should be sealed at all penefrations and laps. Moisture vapor transmission may be additionally reduced by use of concrete additives. Moisture barriers (i.e. plastic sheeting) can retard, but not eliminate moisture vapor movement from the underlying soils up through the slabs. We recommend that the floor covering installer test the moisture vapor flux rate prior to attempting applications of the flooring. "Breathable" floor coverings should be considered if the vapor flux rates are high. A slipsheet or equivalent should be utilized above the concrete slab if crack-sensitive floor coverings (such as ceramic tiles, etc.) are to be placed directly on the concrete slab. Our experience indicates that use of reinforcement in slabs and foundations will generally reduce the potential for drying and shrinkage cracking. However, some cracking should be expected as the concrete cures. Minor cracking is considered normal; however, it is often aggravated by a high water/cement ratio, high concrete temperature at the time of placement, small nominal aggregate size, and rapid moisture loss due to hot, dry and/or windy weather conditions during placement and curing. Cracking due to temperature and moisture fluctuations can also be expected. The use of low slump concrete (not exceeding 4 to 5 inches at the time of placement) can reduce the potential for shrinkage cracking and the action of tensioning the tendons can close small shrinkage cracks. In addition to the careful control of water/cement ratios and slump of concrete, application of 50 percent of the design post-tensioning load within three to four days of slab pour is found to be an effective method of reducing the cracking potential. -19- Leighton 971009-014 The slab subgrade soils underlying the post-tensioned foundation systems should be presoaked as indicated in Section 5.2.1 prior to placement of the moisture barrier and slab concrete. 5.2.1 Moisture Conditioning The slab subgrade soils underlying the post-tensioned foundation systems of the proposed stractures should be presoaked in accordance with the recommendations presented in Table 3 prior to placement of the moisture banier and slab concrete. The subgrade soil moisture content should be checked by a representative of Leighton and Associates prior to slab constraction. Presoaking or moisture conditioning may be achieved in a number of ways, but based on our professional experience, we have found that minimizing the moisture loss of pads that have been completed (by periodic wetting to keep the upper portion ofthe pad from drying out) and/or berming the lot and flooding if for a short period of time (days to a few weeks) are some of the more efficient ways to meet the presoaking requirements. If flooding is performed, a couple of days to let the upper portion ofthe pad dry out and form a cmst so equipment can be utilized should be anticipated. Table 3 Presaturation Recommendations Based on Finish Grade Soil Expansion Potential Presaturation Criteria Expansion Potential (per UBC 18-1-B) Presaturation Criteria Very Low (0-20) Low (21-50) Medium (51-90) High (91-130) Minimum Presoaking Depth (in inches) 6 12 18 24 Minimum Recommended Moisture Content Near optimum moisture 1.2 times optimum moisture 1.2 times optimum moisture 1.3 times optimum moisture 5.2.2 Seismic Design Parameters The site lies within Seismic Zone 4, as defined in the UBC, 1997 edition. The nearest known active fault is the Rose Canyon Fault Zone, which is considered a -20- Leighton 971009-014 Type B Seismic Source (per 1997 UBC criteria) and is located approximately 7.0 miles (or 11.2 kilometers) west of the site. The closest Type A Seismic Source is the Julian segment of the Elsinore Fault Zone, which is located approximately 23.5 miles (or 38 kilometers) east of the site. The following data should be considered for the seismic analysis of the proposed stractures: Causative Fault: Rose Canyon Fault Zone Maximum Magnitude: 7.2 Seismic Source Type: B Seismic Zone Factor: 0.40 Soil Profile Tvpe: Sc Near Source Factors: Na= 1.0/Nv - 1.0 5.2.3 Foundation Setback We recommend a minimum horizontal setback distance from the face of slopes or adjacent retaining walls for all stractural foundations, footings, and other settlement- sensitive stractures as indicated on Table 4. This distance is measured from the outside bottom edge of the footing, horizontally to the slope face and is based on the slope height and type of soil. However, the foundation setback distance may be revised by the geotechnical consultant on a case-by-case basis if the geotechnical conditions are different than anticipated. 4 -21- Leighton 971009-014 Table 4 Minimum Foundation Setback from Slope Faces Slope Height Minimum Recommended Foundation Setback Less than 5 feet 5 feet 5 to 15 feet 7 feet 15 to 30 feet 10 feet Greater than 30 feet 20 feet Please note that the soils within the stractural setback area possess poor lateral stability, and improvements (such as retaining walls, sidewalks, fences, pavements, etc.) constmcted within this setback area may be subject to lateral movement and/or differential settlement. Potential disfress to such improvements may be mitigated by providing a deepened footing or a pier and grade beam foundation system to support the improvement. The deepened footing should meet the setback as described above. 5.2.4 Anticipated Settlement Settlement is anticipated to occur at varying times over the life of the project. Short- term settlement typically occurs upon application of the foundation loads and is essentially completed within the constraction period. Long-term (hydroconsolidation) settlement typically occurs in deep fills upon additional water inflitration into the fill soils (even in properly compacted fill soils and even with subdrains provided). This settlement typically occurs over many years. The total fiiture settlement is expected to be order of 1/2 to 2 inches and differential settlement is estimated to be on the order of 1/2 inch to 1-1/2 inches. 5.3 Lateral Earth Pressures The recommended lateral pressures for the onsite very low to low expansive soil (expansion index less than 50 per UBC Table 18-I-B) or medium expansive soil (expansion index between 51 and 90 per UBC Table 18-I-B) and level or sloping backfill are presented on Table 5. High to very high expansive soils (having an expansion potential greater than 91 per UBC Table 18-I-B) should not be used as backfill soils. -22-4 Leighton 971009-014 Table 5 Lateral Earth Pressures Conditions Equivalent Fluid Weight (pcf) Conditions Very Low to Low Expansive Soils Medium Expansive Soils Conditions Expansion Index less than 50 Expansion Index between 51 and 90 Conditions Level 2:1 Slope Level 2:1 Slope Active 35 55 60 70 At-Rest 55 65 70 80 Passive 350 150 350 150 Embedded stractural walls should be designed for lateral earth pressures exerted on them. The magnitude of these pressures depends on the amount of deformation that the wall can yield under load. If the wall can yield enough to mobilize the fiall shear strength of the soil, it can be designed for "active" pressure. If the wall cannot yield under the applied load, the shear strength of the soil cannot be mobilized and the earth pressure will be higher. Such walls should be designed for "at rest" conditions. If a stmcture moves toward the soils, the resulting resistance developed by the soil is the "passive" resistance. The above noted passive resistance assumes an appropriate setback per Section 5.2.3. For design purposes, the reconimended equivalent fluid pressure for each case for walls founded above the static ground water and backfilied with soils of very low to low expansion potential or medium expansion potential is provided on Table 5. The equivalent fluid pressure values assume free-draining conditions. If conditions other than those assumed above are anticipated, the equivalent fluid pressures values should be provided on an individual-case basis by the geotechnical engineer. The geotechnical and stmctural engineer should evaluate surcharge-loading effects from the adjacent stmctures. All retaining wall stractures should be provided with appropriate drainage and appropriately waterproofed. The outiet pipe should be sloped to drain to a suitable outlet. Typical wall drainage design is illusfrated in Appendix C. For sliding resistance, the friction coefficient of 0.35 may be used at the concrete and soil interface. In combining the total lateral resistance, the passive pressure or the frictional resistance should be reduced by 50 percent. Wall footings should be designed in accordance with stractifral considerations. The passive resistance value may be increased by one-third when considering loads of short duration including wind or seismic loads. The horizontal distance between foundation elements providing passive resistance should be minimum of -23- Leighton 971009-014 three times the depth of the elements to allow fiall development of these passive pressures. The total depth of retained earth for the design of cantilever walls should be the vertical distance below the ground surface measured at the wall face for stem design or measured at the heel of the footing for overtuming and sliding. All wall backcuts should be made in accordance with the cunent OSHA requirements. The granular and native backfill soils should be compacted to at least 90 percent relative compaction (based on ASTM Test Method D1557). The granular fill should extend horizontally to a minimum distance equal to one-half the wall height behind the walls. The walls should be constmcted and backfllled as soon as possible after backcut excavations. Prolonged exposure of backcut slopes may result in some localized slope instability Foundations for retaining walls in competent formational soils or properly compacted fill should be embedded at least 18 inches below lowest adjacent grade. At this depth, an allowable bearing capacity of 2,000 psf may be assumed. 5.4 Fences and Freestanding Walls Footings for freestanding walls should be founded a minimum of 18 inches below lowest adjacent grade (or 30 inches for walls founded on high expansive soils). To reduce the potential for unsightly cracks in freestanding walls, we recommend inclusion of constraction joints at a maximum of 15-foot intervals. This spacing may be altered in accordance with the recommendations of the stractural engineer, based on wall reinforcement details. Our experience on similar sites in older developments indicates that walls on shallow foundations near the top-of-slopes tend to tilt excessively over time as a result of slope creep. If the effects of slope creep on top-of-slope walls are not deemed acceptable, one or a combination of the options provided in the following paragraphs should be utilized in the design of such stmctures, based on the desired level of mitigation of creep-related effects on them. A relatively inexpensive option to address creep related problems in top-of-slope walls and fences is to allow some degree of creep damage and design the stractures so that tilting or cracking will be less visually obvious, or such that they may be economically repaired or replaced. If, however, a better degree of creep mitigation is desired, the walls and fences may be provided with the deepened footings to met the foundation setback criteria laid out in Figure 18-1-1 of the UBC, 1997 edition, or these stractures may be constmcted to accommodate potential movement. Under certain circumstances, an effective solution to minimize the effects of creep on top- of-slope walls and fences is to support these stmctures on a pier-and-grade-beam system. The piers normally consist of minimum 12-inch diameter cast-in-place caissons spaced at a -24- Leighton 971009-014 maximum of 8 feet on center, and connected together by a minimum 12-inch-thick grade beam at a shallow depth. The piers are typically at least 10 feet deep for medium or high expansive soil. The steel reinforcement for the system should be designed with consideration of wall/fence type and loading. Walls or fences aligned essentially perpendicular to the top of the slope are normally supported on the pier-and-grade-beam system for at least that part of the wall that is within 15 feet from the top-of-slope. Caisson support is reconimended for all top-of-slope walls where slopes are greater than 10 feet in height. And the slopes consist of high or very high expansive soils. 5.5 Concrete In-place concrete is subject to adverse conditions such as unsightly cracking, excessive water vapor transmission, sulfate attack, efflorescence, and other adverse conditions. Adherence to the following guidelines will help mitigate against the above adverse hazards. 1) Exposure to sulfate-containing solutions: • The soluble sulfate content of the finish grade soils on the site are anticipated to be in the negligible to severe range based on 1997 Uniform Building Code criteria. • Comply with 1997 UBC Table 19-A-4; and • Maintain concrete water/cement ratio less than 0.5. 2) Drying shrinkage cracking: • Follow recommendations of ACI 302.IF for industrial/commercial stmctures, or follow recommendations of ACI 332.R for residential constraction, as appropriate; • Maintain concrete water/cement ratio less than 0.5. • Use minimum cement required to achieve desired sfrength; • Provide effective concrete curing for seven days after placing; • Design control joints into slab; and • Do not place concrete on hot, windy low-humidity days. 3) Reduction of vapor transmission: • Maintain concrete water/cement ratio less than 0.5. • Avoid constraction punctures of vapor barriers; • Seal vapor banier j oints; • Extend vapor barrier into footing/grade beam excavation (not covering bottom of excavation); • Prevent excessive inigation of landscaping; and • Use floor-covering adhesives that are not water-soluble. -25- Leighton 971009-014 5.6 Slope Maintenance Guidelines It is the responsibility of the owner to maintain the slopes, including adequate planting, proper inigation and maintenance, and repair of faulty inigation systems. To reduce the potential for erosion and slumping of graded slopes, all slopes should be planted with ground cover, shrabs, and plants that develop dense, deep root stractures and require minimal inigation. Slope planting should be canied out as soon as practical upon completion of grading. Surface-water ranoff and standing water at the top-of-slopes should be avoided. Oversteepening of slopes should be avoided during constraction activities and landscaping. Maintenance of proper lot drainage, undertaking of property improvements in accordance with sound engineering practices, and proper maintenance of vegetation, including regular slope inigation, should be performed. Slope inigation sprinklers should be adjusted to provide maximum uniform coverage with minimal of water usage and overlap. Overwatering and consequent mnoff and ground saturation should be avoided. If automatic sprinklers systems are installed, their use must be adjusted to account for rainfall conditions. Trenches excavated on a slope face for any purpose should be properly backfllled and compacted in order to obtain a minimum of 90 percent relative compaction, in accordance with ASTM Test Method D1557. Observation/testing and acceptance by the geotechnical consultant during trench backflll is reconimended. A rodent-control program should be established and maintained. Prior to planting, recently graded slopes should be temporarily protected against erosion resulting from rainfall, by the implementing slope protection measures such as polymer covering, jute mesh, etc. 5.7 Control of Surface Water and Drainage Surface drainage should be carefially taken into consideration during precise grading, landscaping, and building constmction. Positive drainage (e.g., roof gutters, downspouts, area drain, etc.) should be provided to direct surface water away from stractures and towards the street or suitable drainage devices. Ponding of water adjacent to stractures should be avoided; roof gutters, downspouts, and area drains should be aligned so as to transport surface water to a minimum distance of 5 feet away from stmctures. The performance of stmctural foundations is dependent upon maintaining adequate surface drainage away from stractures. Water should be transported off the site in approved drainage devices or unobstracted swales. We recommend that the minimum flow gradient for the drainage be 1 -percent for area drains and paved drainage swales; and 2-percent for unpaved drainage swales. We recommend that where stractures will be located within 5 feet of a proposed drainage swale, the surface drainage adjacent to the stractures be accomplished with a gradient of at least 3-1/2 percent away from the stmcture for a minimum horizontal distance of 3 feet. Drainage should be further maintained by a swale or drainage path at a gradient of at least -26- Leighton 971009-014 1-percent for area drains and paved drainage swales and 2-percent for unpaved drainage swales to a suitable collection device (i.e. area drain, street gutter, etc.). We also recommend that stractural footings within 4 feet of the drainage swale flowline be deepened so that the bottom of the footing is at least 12 inches below the flow-line of the drainage swale. In places where the prospect of maintaining the minimum reconimended gradient for the drainage swales and the constraction of additional area drains is not feasible, provisions for specific recommendations may be necessary, outlining the importance of maintaining positive drainage. The impact of heavy inigation or inadequate runoff gradient can create perched water conditions, resulting in seepage or shallow groundwater conditions where previously none existed. Maintaining adequate surface drainage and controlled irrigation will significantly reduce the potential for nuisance-type moisture problems. To reduce differential earth movements (such as heaving and shrinkage due to the change in moisture content of foundation soils, which may cause distress to a stracture or improvement), the moisture content of the soils sunounding the stracture should be kept as relatively constant as possible. All area drain inlets should be maintained and kept clear of debris in order to function properly. In addition, yard landscaping should not cause any obstraction to the yard drainage. Rerouting of yard drainage pattem and/or installation of area drains should be perfonned, if necessary. A qualified civil engineer or a landscape architect should be consulted prior to rerouting of drainage. 5.8 Landscaping and Post-Construction Landscaping and post-constmction practices carried out by the owner(s) and their representative bodies exert significant influences on the integrity of stractures founded on expansive soils. Improper landscaping and post-constraction practices, which are beyond the confrol of the geotechnical engineer, are frequently the primary cause of distress to these stractures. Recommendations for proper landscaping and post-constmction practices are provided in the following paragraphs within this section. Adhering to these recommendations wdll help in minimizing distress due to expansive soils, and in ensuring that such effects are limited to cosmetic damages, without compromising the overall integrity of stmctures. The recommendations provided herein have been developed in general accordance with the guidelines provided within the Post-Tensioning Institute's (1996) recommendations for the design and constraction of post-tensioned slabs-on-ground. Initial landscaping should be done on all sides adjacent to the foundation of a stmcture, and adequate measures should be taken to ensure drainage of water away from the foundation. If larger, shade providing trees are desired, such trees should be planted away from stmctures (at a minimum distance equal to half the mature height of the tree) in order to prevent penetration of the tree roots beneath the foundation of the stracture. -27- Leighton 971009-014 Locating planters adjacent to buildings or stractures should be avoided as much as possible. If planters are utilized in these locations, they should be properly designed so as to prevent fluctuations in the moisture content of subgrade soils. Planting areas at grade should be provided with appropriate positive drainage. Wherever possible, exposed soil areas should be above paved grades. Planters should not be depressed below adjacent paved grades unless provisions for drainage, such as catch basins and drains, are made. Adequate drainage gradients, devices, and curbing should be provided to prevent ranoff from adjacent pavement or walks into planting areas. Watering should be done in a uniform, systematic manner as equally as possible on all sides of the foundation, to keep the soil moist. Irrigation methods should promote uniformity of moisture in planters and beneath adjacent concrete flatwork. Overwatering and underwatering of landscape areas must be avoided. Areas of soil that do no have ground cover may require more moisture, as they are more susceptible to evaporation. Ponding or trapping of water in localized areas adjacent to the foundations can cause differential moisture levels in subsurface soils and should, therefore, not be allowed. Trees located within a distance of 20 feet of foimdations would require more water in periods of extreme drought, and in some cases, a root injection system may be required to maintain moisture equilibrium. During exfreme hot and dry periods, close observations should be carried out around foundations to ensure that adequate watering is being undertaken to prevent soil from separating or pulling back from the foundations. 5.9 Construction Observation and Testing Constraction observation and testing should be performed by the geotechnical consultant during ftiture excavations and foundation or retaining wall constraction on the graded portions of the site. Additionally, footing excavations should be observed and moisture determination tests of subgrade soils should be performed by the geotechnical consultant prior to the pouring of concrete. Foundation design plans should also be reviewed by the geotechnical consultant prior to excavations. -28- Leighton 971009-014 6.0 LIMITATIONS The presence of our field representative at the site was intended to provide the owner with professional advice, opinions, and recommendations based on observations of the confractor's work. Although the observations did not reveal obvious deficiencies or deviations from project specifications, we do not guarantee the contractor's work, nor do our services relieve the contractor or his subcontractor's work, nor do our services relieve the confractor or his subcontractors of their responsibility if defects are subsequently discovered in their work. Our responsibilities did not include any supervision or direction of the actual work procedures of the contractor, his personnel, or subconfractors. The conclusions in this report are based on test results and observations of the grading and earthwork procedures used and represent our engineering opinion as to the compliance of the results with the project specifications. -29- Leighton 971009-014 Table 1 Lot-By-Lot Summary of /^s-Graded Geotechnical Conditions Model and Phase 1 Production Lots Lot Number Lot Type Finish Grade Expansion Potential Approximate Maximum Fill Thickness on Lot (in feet) Approximate Differential Fill Thickness Across Proposed Building Footprint (in feet) PA-6 Model Lot Complex 60 Fill Medium 35 20 61 Fill Medium 30 20 62 Fill Medium 30 20 63 Fill Medium 25 20 PA-7 Model Lot Complex 112 Fill Medium 15 11 156 Transition Medium 5 2 157 Fill Medium 10 6 158 Fill Medium 25 15 159 Fill Medium 35 10 PA-8 Model Lot Complex 169 Overexcavation Medium 4 I 170 Overexcavation Medium 4 I 171 Transition Medium 20 15 172 Fill Medium 30 10 PA-9 Model Lot Complex 269 Overexcavation Low 5 1 270 Overexcavation Low 5 I 271 Overexcavation Low 5 1 272 Overexcavation Low 5 1 PA-10 Model Lot Complex 374 Fill Low 30 20 T-l 971009-014 Table 1 Lot-By-Lot Summary of As-Graded Geotechnical Conditions Model and Phase 1 Production Lots Lot Number Lot Type Finish Grade Expansion Potential Approximate Maximum Fill Thickness on Lot (in feet) Approximate Differential Fill Thickness Across Proposed Building Footprint (in feet) PA-10 Model Lot Complex (continued) 375 Transition Low 6 2 376 Transition Low 6 2 377 Transition Low 7 I PA-12 Model Lot Complex 448 Fill Low 75 15 449 Fill Low 75 20 450 Fill Medium 80 15 451 Fill Medium 80 15 452 Fill Medium 80 15 PA-6 Phase 1 Production Lots 30 Fill High 35 25 31 Fill Medium 25 15 32 Fill Medium 20 10 33 Fill Medium 20 10 34 Fill Medium 20 10 55 Fill Low 55 15 56 Fill Low 55 10 57 Fill Medium 55 10 58 Fill Medium 60 20 59 Fill Medium 55 30 380 Overexcavation Low 7 2 381 Transition Low 8 2 382 Transition Low 6 2 383 Overexcavation Low 6 1 T-2 971009-014 Table 1 Lot-By-Lot Summary of As-Graded Geotechniral Conditions Model and Phase 1 Production Lots Lot Number Lot Type Finish Grade Expansion Potential Approximate Maximum Fill Thickness on Lot (in feet) Approximate Differential Fill Thickness Across Proposed Building Footprint (in feet) PA-6 Phase 1 Production Lots (Continued) 404 Cut Very Low 0 0 405 Cut Very Low 0 0 406 Cut Very Low 0 0 407 Overexcavation Low 5 1 408 Overexcavation Low 5 1 409 Overexcavation Low 5 1 410 Overexcavation Low 5 1 411 Overexcavation High 5 1 PA-7 Phase 1 Production Lots 127 Overexcavation Medium 4 1 128 Overexcavation Medium 4 I 129 Overexcavation Medium 4 1 130 Overexcavation Medium 4 1 131 Overexcavation Medium 4 1 132 Overexcavation High 4 1 133 Overexcavation High 4 I 134 Overexcavation High 4 1 135 Overexcavation High 4 1 136 Transition High 10 137 Overexcavation Medium 4 1 138 Overexcavation Medium 4 1 139 Overexcavation Medium 4 1 140 Overexcavation Medium 4 1 141 Overexcavation Medium 4 1 T-3 971009-014 Table 1 Lot-By-Lot Summary of As-Graded Geotechnical Conditions Model and Phase 1 Production Lots Lot Number Lot Type Finish Grade Expansion Potential Approximate Maximum Fill Thickness on Lot (in feet) Approximate Differential Fill Thickness Across Proposed Building Footprint (in feet) PA-7 Phase 1 Production Lots (Continued) 142 Overexcavation Medium 4 1 143 Overexcavation Medium 4 1 180 Overexcavation Low 4 1 181 Overexcavation Low 4 1 182 Overexcavation Medium 4 1 183 Overexcavation Medium 4 I 184 Overexcavation Medium 4 1 185 Overexcavation Medium 4 1 186 Overexcavation Medium 4 1 187 Transition Medium 10 188 Overexcavation Medium 4 1 189 Overexcavation Medium 4 1 190 Overexcavation Medium 4 1 191 Overexcavation Medium 4 1 192 Overexcavation Medium 4 1 193 Overexcavation Medium 4 1 PA-9 Phase 1 Production Lots 263 Overexcavation Low 4 1 264 Overexcavation Low 5 2 265 Fill Low 35 25 266 Fill Low 30 20 267 Fill Low 20 10 268 Overexcavation Low 5 1 281 Overexcavation Low 4 1 T-4 971009-014 Table 1 Lot-By-Lot Summary of As-Graded Geotechnical Conditions Model and Phase 1 Production Lots Lot Number Lot Type Finish Grade Expansion Potential Approximate Maximum Fill Thickness on Lot (in feet) Approximate Differential Fill Thickness Across Proposed Building Footprint (in feet) PA-9 Phase 1 Production Lots (Continued) 282 Overexcavation Low 4 1 283 Overexcavation Low 4 1 284 Overexcavation Low 4 I PA-10 Phase 1 Production Lots I Fill Low 100 10 2 Fill Low 100 30 3 Fill Low 70 35 4 Fill Low 55 25 5 Fill Low 20 10 6 Fill Low 15 10 7 Transition Low 10 3 8 Transition Low 5 1 9 Overexcavation Low 5 1 10 Overexcavation Medium 5 1 11 Overexcavation Medium 5 1 12 Overexcavation Medium 5 I 13 Overexcavation Medium 5 I PA-12 Phase 1 Production Lots 427 Fill Medium 65 20 428 Fill Medium 55 20 429 Fill Medium 50 20 430 Fill Medium 50 20 431 Fill Medium 50 15 432 Fill Medium 55 20 T-5 971009-014 Table 1 Lot-By-Lot Summary of As-Graded Geotechnical Conditions Model and Phase 1 Production Lots Lot Number Lot Type Finish Grade Expansion Potential Approximate Maximum Fill Thickness on Lot (in feet) Approximate Differential Fill Thickness Across Proposed Building Footprint (in feet) PA-12 Phase 1 Production Lots (Continued) 433 Fill Medium 55 20 434 Fill Medium 70 20 435 Fill Low 35 15 436 Fill Low 25 15 437 Fill Low 15 10 438 Fill Low 12 8 439 Fill Low 20 15 440 Fill Low 55 25 441 Fill Low 55 35 442 Fill Low 55 35 443 Fill Low 55 35 T-6 971009-014 APPENDIX A References Califomia Building Standards Commission (CBSC), 2001, Califomia Building Code, Volume I - Adminisfrative, Fire- and Life-Safety, and Field Inspection Provision, Volume II - Stractural Engineering Design Provision, and Volume III - Material, Testing and Installation Provision, ICBO. Hart, E.W., 1997, Fault-Rupture Hazard Zones in Califomia, Alquist-Priolo Special Studies Zones Act of 1972 with Index to Special Studies Zones Maps: Department of Conservation, Division of Mines and Geology, Special Publication 42. Intemational Conference of Building Officials (ICBO), 1997, Uniform Building Code, Volume I - Administrative, Fire- and Life-Safety, and Field Inspection Provisions, Volume II - Stmctural Engineering Design Provisions, and Volume III - Material, Testing and Installation Provision, ICBO. Leighton and Associates, Inc., 1997, Preliminary Geotechnical Investigation, Bressi Ranch, Carlsbad, Califomia, Project No. 4971009-002, dated July 29, 1997. , 2001, Supplemental Geotechnical Investigation for Mass Grading, Bressi Ranch, Carisbad, Califomia, ProjectNo. 971009-0015, dated March 14, 2001. —, 2003a, Geotechnical Grading Plan Review of the Mass Grading plans, Bressi Ranch, Carlsbad, Cahfomia, ProjectNo. 971009-007, dated January 17, 2003. —, 2003b, Preliminary Residential and Commercial Foundation Design Recommendations, Bressi Ranch, Carlsbad, Califomia, Project No. 971009-007, dated Febmary 5, 2003. - 2003c, Geotechnical Recommendations Conceming 95 Percent Relative Compaction of Fills Deeper than 40 Feet, Bressi Ranch, Carlsbad, Califomia, Project No. 971009-007, dated Febmary 13, 2003. 2003d, Reconimended Type of Pipe for Proposed Subdrains, Bressi Ranch, Carlsbad, Califomia, ProjectNo. 971009-007, dated April 17, 2003. 2003e, Advanced Preliminary Street Pavement Sections Based on Assumed Street Subgrade Soil R-Values and Traffic Indexes, Bressi Ranch, Carlsbad, Califomia, August 8,2003, dated August 8, 2003. 2003f, Side-Yard Drainage Recommendation Altemative, Bressi Ranch, Carlsbad, Califomia, Project No. 971009-014, dated August 28, 2003. A-l 971009-014 APPENDIX A (continued) Project Design Consultants, 2003a, Mass Grading and Erosion Control Plans for: Bressi Ranch, Carlsbad, Califomia, Carlsbad Tract No. 00-06, Drawing No. 400-8A; dated January 7,2003, revised November 24,2003. , 2003b, Grading and Erosion Control Plans: Bressi Ranch Planning Area 7, Unit No. 2, Carlsbad Tract No. CT 02-14(2), Carlsbad, Califomia, Drawing No. 411-4A, 9 Sheets, dated December 19,2003. -, 2003c, Grading and Erosion Confrol Plans: Bressi Ranch Planning Area 8, Unit No. 3, Carlsbad Tract No. CT 02-14(3), Carlsbad, Califomia, Drawing No. 411-8A, 9 Sheets, dated December 19, 2003. - 2003d, Grading and Erosion Control Plans: Bressi Ranch Planning Area 9, Unit No. 4, Carlsbad Tract No. CT 02-14(4), Carlsbad, Califomia, Drawing No. 411-7A, 9 Sheets, dated December 21,2003. 2004a, Grading and Erosion Control Plans: Bressi Ranch Planning Area 6, Unit No. 1, Carlsbad Tract No. CT 02-14(1), Carlsbad, Califomia, Drawing No. 411-3A, 7 Sheets, dated Febraary 3, 2004. - 2004b, Grading and Erosion Control Plans: Bressi Ranch Planning Area 10, Unit No. 5, Carlsbad Tract No. CT 02-14(5), Carisbad, Cahfomia, Drawing No. 411-1 A, 9 Sheets, dated Febraary 3,2004. 2004c, Grading and Erosion Control Plans: Bressi Ranch Planning Area 12, Unit No. 6, Carlsbad Tract No. CT 02-14, Carlsbad, Califomia, Drawing No. 411-2A, 9 Sheets, dated Febmary 3,2004. A-2 971009-014 APPENDIX B •aboratory Te.sting Procedures and Test Results; Maximum Densitv Tests: The maximum dry density and optimum moisture content of typical soils were determined in accordance with ASTM Test Method D1557. The results of these tests are presented in the table below: Sample Number Sample Description Maximum Dry Density (pcf) Optimum Moisture Content (%) I Light-brown clayey SAND (Alluvium) 125.0 11.0 2 Brown sandy silfy CLAY (Alluvium) 122.5 11.5 3 Light-brown silfy clayey SAND (Alluvium) 122.0 11.0 4 Olive-brown clayey SAND (Alluvium) 120.5 12.5 5 Olive brown sandy CLAY (Alluvium) 124.0 12.0 6 Red-brown sandy CLAY (Alluvium) 122.5 11.5 7 Olive light brown silty fme SAND 122.0 13.0 8 Gray Brown to Olive Brown clayey silfy fme SAND 117.5 14.0 9 Light Olive-gray clayey silty SAND 118.0 15.0 10 Light brown Clayey very fine SAND 112.5 16.0 11 Brown clayey SAND (fill mix) 120.0 13.0 12 Brown clayey SAND (fill mix) 120.0 12.5 13 Dark brown sandy CLAY (Alluvium) 115.0 16.5 14 Light brown olive brown 124.0 12.0 15 Light gray brown silfy very fine to fme SAND 112.0 15.5 16 Light gray fine sand 117.0 14.0 17 Light yellow-brown clayey silty SAND 114.0 14.5 18 Light olive brown silfy clayey SAND 113.0 16.0 19 Yellow brown clayey silfy SAND 118.0 15.0 20 Pale Olive light brown clayey silfy SAND 116.0 14.0 21 Pale Olive light brown clayey silfy SAND 118.0 13.0 B-l APPENDIX B(Continued) 971009-014 Sample Number Sample Description Maximum Dry Density (pcf) Optimum Moisture Content (%) 22 Pale olive to gray brown silfy sand 124.0 12.0 23 Pale Olive to Gray brown clayey silfy SAND 119.0 13.0 24 Yellow-Brown Clayey SAND 116.0 13.5 25 Brown CLAY 104.0 19.0 26 Olive Gray CLAY 112.0 17.0 27 Yellow-Brown Clayey SAND 118.5 14.0 28 Brown Silfy SAND 126.0 9.5 Expansion Index Tests: The expansion potential of selected materials was evaluated by the Expansion Index Test, UBC Standard No. 18-2. Specimens are molded under a given compactive energy to approximately the optimum moisture content and approximately 90 percent relative compaction. The prepared 1-inch thick by 4-inch diameter specimens are loaded to an equivalent 144 psf surcharge and are inundated with distilled water until volumetric equilibrium is reach. The results of these tests are presented in the table below: Sample Number Representative Lots Sample Location Soil Type Expansion Index Expansion Potential* E12 Lots 13-15 Lot 14 Yellow-brown sandy CLAY 51 Medium E13 Lots 10-12 Lot 11 Yellow-brown sandy CLAY 63 Medium E14 Lots 7-9 Lots Olive-brown silfy SAND 32 Low E15 Lots 4-6 Lot 5 Yellow-brown silfy SAND 39 Low E16 Lots 60-63 Lot 62 Yellow-brown sandy CLAY 76 Medium E17 Lots 57-59 Lot 59 Brown sandy CLAY 85 Medium E18 Lots 55-56 Lot 56 Yellow-brown silfy SAND 27 Low E19 Lots 1-3 Lot 2 Yellow-brown silty SAND 47 Low E26 Lots 28-30 Lot 28 Dark brown sandy CLAY 92 High E27 Lots 31-34 Lot 31 Light brown clayey SAND 56 Medium B-2 APPENDIX B (Continued) 971009-014 Sample Number Representative Lots Sample Location Soil Type Expansion Index Expansion Potential* E40 Lots 380-383 Lot 381 Pale gray silfy SAND 22 Low E41 Lots 377-379 Lot 378 Yellow-brown silfy clayey SAND 23 Low E42 Lots 374-376 Lot 374 Yellow-brown silfy clayey SAND 28 Low E45 Lots 404-406 Lot 405 Pale gray silfy SAND 6 Very Low E46 Lots 450-452 Lot 451 YeUow-brown sandy SILT 56 Medium E47 . Lots 447-449 Lot 447 Yellow-brown silty clayey SAND 38 Low E50 Lots 425-429 Lot 427 Pale gray sandy SILT 66 Medium E51 Lots 430-434 Lot 432 Pale gray sandy CLAY 77 Medium E54 Lots 439-443 Lot 441 Pale gray silfy clayey SAND 42 Low E55 Lots 435-438 Lot 437 Pale gray silfy clayey SAND 23 Low ESS Lots 127-131 Lot 128 Olive-brown sandy CLAY 83 Medium E59 Lots 132-136 Lot 133 Yellow-brown sandy CLAY 102 High E60 Lots 137-140 Lot 139 Olive-brown sandy CLAY 76 Medium E61 Lots 141-143 Lot 142 Brown clayey SAND to sandy CLAY 67 Medium E65 Lots 407-410 Lot 409 YeUow-brown silfy clayey SAND 27 Low E66 Lots 411-414 Lot413 Olive-brown sandy CLAY 111 High E76 Lots 263-267 Lot 270 Yellow-brown silfy clayey SAND 24 Low E77 Lots 268-272 Lot 270 Yellow-brown silfy clayey SAND 26 Low E91 Lots 112-115 Lot 113 Olive-brown sandy SILT 56 Medium B-3 971009-014 APPENDIX B(Continued) Sample Number Representative Lots Sample Location Soil Type Expansion Index Expansion Potential* E94 Lots 156-159 Lot 158 Yellow-brown sandy SILT 51 Medium ElOO Lots 279-284 Lot 281 Yellow-brown silfy SAND 38 Low E102 Lots 168-172 Lot 169 Brown sandy SILT 55 Medium E104 Lots 177-181 Lot 180 Yellow-Brown sandy SILT 29 Low E105 Lots 182-186 Lot 185 Yellow-brown sandy 60 Medium E106 Lots 187-190 Lot 188 Olive-brown sandy CLAY 83 Medium E107 Lots 191-195 Lot 194 Olive-brown silty SAND 31 Low * Based on the 1997 edition ofthe Uniform Building Code Table 18-I-B. Soluble Sulfates: The soluble sulfate contents of selected samples were determined by standard geochemical methods. The test results are presented in the table below: Sample Location Sample Description Sulfate Content (%) Potential Degree of Sulfate Attack* Lot 14 Yellow-brown sandy CLAY 0.10 Moderate Lot 11 YeUow-brown sandy CLAY 0.125 Moderate Lots Olive-brown silfy SAND 0.05 NegUgible Lots Yellow-brown silfy SAND 0.07 Negligible Lot 62 YeUow-brown sandy CLAY 0.06 Negligible Lot 59 Brown sandy CLAY < 0.015 Negligible Lot 56 YeUow-brown sllty SAND 0.021 Negligible Lot 2 Yellow-brown silty SAND 0.15 Moderate Lot 28 Dark brown sandy CLAY 0.021 Negligible Lot 31 Light brown clayey SAND 0.018 Negligible Lot 381 Pale gray silfy SAND <0.015 Negligible B-4 APPENDIX B(Continued) 971009-014 Sample Location Sample Description Sulfate Content (%) Potential Degree of Sulfate Attack* Lot 378 YeUow-brown silfy clayey SAND <0.015 Negligible Lot 374 YeUow-brown silfy clayey SAND <0.015 Negligible Lot 405 Pale gray silfy SAND <0.015 Negligible Lot 451 YeUow-brown sandy SILT 0.10 Moderate Lot 447 YeUow-brown silty clayey SAND 0.063 Negligible Lot 427 Pale gray sandy SILT 0.10 Moderate Lot 432 Pale gray sandy CLAY 0.10 Moderate Lot 441 Pale gray silfy clayey SAND 0.063 Negligible Lot 437 Pale gray silfy clayey SAND 0.075 Negligible Lot 128 Olive-brown sandy CLAY 0.063 Negligible Lot 133 YeUow-brown sandy CLAY 0.027 Negligible Lot 139 Olive-brown sandy CLAY 0.06 Negligible Lot 142 Brown clayey SAND to sandy CLAY 0.075 Negligible Lot 409 YeUow-brown silfy clayey SAND 0.15 Moderate Lot 413 Olive-brown sandy CLAY 0.20 Severe Lot 265 YeUow-brown silfy clayey SAND 0.06 Negligible Lot 270 YeUow-brown silfy clayey SAND 0.15 Moderate Lot 113 Olive-brown sandy SILT 0.20 Severe Lot 158 YeUow-brown sandy SILT 0.125 Moderate Lot 181 YeUow-brown silty SAND 0.075 Negligible B-5 971009-014 APPENDIX B(Continued) Sample Location Sample Description Sulfate Content (%) Potential Degree of Sulfate Attack* Lot 169 Brown sandy SILT 0.10 Moderate Lot 180 Yellow-Brown sandy SILT 0.03 Negligible Lot 185 YeUow-brown sandy 0.062 Negligible Lot 188 Olive-brown sandy CLAY 0.035 Negligible Lot 194 Olive-brown silfy SAND 0.10 Moderate * Based on the 1997 edition of the Uniform Building Code Table 19-A-4. B-6 Leightonand Associates,Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 1 of 6 LEIGHTON AND ASSOCIATES, INC. GENERAL EARTHWORK AND GRADING SPECIFICATIONSFOR ROUGH GRADING General 1.1 Intent: These General Earthwork and Grading Specifications are for the grading and earthwork shown on the approved grading plan(s) and/or indicated in the geotechnical report(s). These Specifications are a part of the recommendations contained in the geotechnical report(s). In case of conflict, the specific recommendations in the geotechnical report shall supersede these more general Specifications. Observations of the earthwork by the project Geotechnical Consultant during the course of grading may result in new or revised recommendations that could supersede these specifications or the recommendations in the geotechnical report(s). 1.2 The Geotechnical Consuhant of Record: Prior to commencementof work, the owner shall employ the Geotechnical Consultant of Record (Geotechnical Consultant). The Geotechnical Consultants shall be responsible for reviewing the approved geotechnical report(s) and accepting the adequacy of the preliminary geotechnical findings, conclusions, and recommendations prior to the commencementof the grading. Prior to commencement of grading, the Geotechnical Consultant shall review the "work plan" prepared by the Earthwork Contractor (Contractor) and schedule sufficient personnel to perform the appropriate level of observation, mapping, and compaction testing. During the grading and earthwork operations, the Geotechnical Consultant shall observe, map, and document the subsurface exposures to verify the geotechnical design assumptions. If the observed conditions are found to be significantly different than the interpreted assumptions during the design phase, the Geotechnical Consultant shall inform the owner, recommend appropriate changes in design to accommodate the observed conditions, and notify the review agency where required. Subsurface areas to be geotechnically observed, mapped, elevations recorded, and/or tested include natural ground after it has been cleared for receiving fill but before fill is placed, bottoms of all "remedial removal" areas, all key bottoms, and benches made on sloping ground to receive fill. The GeotechnicalConsultantshall observe the moisture-conditioningand processing of the subgrade and fill materials and perform relative compaction testing of fill to determine the attained level of compaction. The Geotechnical Consultant shall provide the test results to the owner and the Contractor on a routine and frequent basis. 3030.1094 Leightonand Associates,Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 2 of 6 1.3 The Earthwork Contractor: The Earthwork Contractor (Contractor) shall be qualified, experienced, and knowledgeable in earthwork logistics, preparation and processing of ground to receive fill, moisture-condhioningand processing of fill, and compacting fill. The Contractor shall review and accept the plans, geotechnical report(s), and these Specifications prior to commencement of grading. The Contractor shall be solely responsible for performing the grading in accordance with the plans and specifications. The Contractor shall prepare and submit to the owner and the Geotechnical Consultant a work plan that indicates the sequence of earthwork grading, the number of "spreads" of work and the estimated quantities of daily earthwork contemplated for the site prior to commencement of grading. The Contractor shall inform the owner and the Geotechnical Consultant of changes in work schedules and updates to the work plan at least 24 hours in advance of such changes so that appropriate observations and tests can be planned and accomplished. The Contractor shall not assume that the Geotechnical Consultant is aware of all grading operations. The Contractor shall have the sole responsibility to provide adequate equipment and methods to accomplish the earthwork in accordance with the applicable grading codes and agency ordinances, these Specifications, and the recommendations in the approved geotechnical report(s) and grading plan(s). If, in the opinion of the Geotechnical Consultant, unsatisfactory conditions, such as unsuitable soil, improper moisture condition, inadequate compaction, insufficient buttress key size, adverse weather, etc., are resulting in a quality of work less than required in these specifications, the Geotechnical Consultant shall reject the work and may recommend to the owner that construction be stopped until the conditions are rectified. 2.0 Preparation of Areas to be Filled 2.1 Clearing and Gmbbing: Vegetation, such as brush, grass, roots, and other deleterious material shall be sufficiently removed and properly disposed of in a method acceptable to the owner, goveming agencies, and the GeotechnicalConsultant. The Geotechnical Consultant shall evaluate the extent of these removals depending on specific site conditions. Earth fill material shall not contain more than I percent of organic materials (by volume). No fill lift shall contain more than 5 percent of organic matter. Nesting of the organic materials shall not be allowed. If potentially hazardous materials are encountered, the Contractor shall stop work in the affected area, and a hazardous material specialist shall be informed immediately for proper evaluation and handling of these materials prior to continuingto work in that area. As presently defined by the State of California, most refined petroleum products (gasoline, diesel fuel, motor oil, grease, coolant, etc.) have chemical constituents that are considered to be hazardous waste. As such, the indiscriminate dumping or spillage of these fluids onto the ground may constitute a misdemeanor, punishable by fines and/or imprisonment, and shall not be allowed. 3030.1094 Leightonand Associates,Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 3 of 6 2.2 Processing: Existing ground that has been declared satisfactory for support of fill by the Geotechnical Consultant shall be scarified to a minimum depth of 6 inches. Existing ground that is not satisfactory shall be overexcavated as specified in the following section. Scarification shall continue until soils are broken down and free of large clay lumps or clods and the working surface is reasonably unifonn, flat, and free of uneven features that would inhibit uniform compaction. 2.3 Overexcavation: In addition to removals and overexcavations recommended in the approved geotechnical report(s) and the grading plan, soft, loose, dry, saturated, spongy, organic-rich, highly fractured or otherwise unsuitable ground shall be overexcavated to competent ground as evaluated by the Geotechnical Consultant during grading. 2.4 Benching: Where fills are to be placed on ground with slopes steeper than 5:1 (horizontal to vertical units), the ground shall be stepped or benched. Please see the Standard Details for a graphic illustration. The lowest bench or key shall be a minimum of 15 feet wide and at least 2 feet deep, into competent material as evaluated by the Geotechnical Consultant. Other benches shall be excavated a minimum height of 4 feet into competent material or as otherwise recommended by the Geotechnical Consultant. Fill placed on ground sloping flatter than 5:1 shall also be benched or otherwise overexcavated to provide a flat subgrade forthefiU. 2.5 Evaluation/Acceptance of Fill Areas: All areas to receive fill, including removal and processed areas, key bottoms, and benches, shall be observed, mapped, elevations recorded, and/or tested prior to being accepted by the Geotechnical Consultant as suitable to receive fill. The Contractor shall obtain a written acceptance from the Geotechnical Consultant prior to fill placement. A licensed surveyor shall provide the survey control for determiningelevationsof processed areas, keys, and benches. 3.0 Fill Material 3.1 General: Material to be used as fill shall be essentially free of organic matter and other deleterious substances evaluated and accepted by the Geotechnical Consultant prior to placement. Soils of poor quality, such as those with unacceptable gradation, high expansion potential, or low strength shall be placed in areas acceptable to the Geotechnical Consuhant or mixed with other soils to achieve satisfactory fill material. 3.2 Oversize: Oversize material defined as rock, or other irreducible material with a maximum dimension greater than 8 inches, shall not be buried or placed in fill unless location, materials, and placement methods are specifically accepted by the Geotechnical Consultant. Placement operations shall be such that nesting of oversized material does not occur and such that oversize material is completely surrounded by compacted or densified fill. Oversize material shall not be placed within 10 vertical feet of finish grade or within 2 feet of future utilities or underground construction. 3030.1094 Leightonand Associates,Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 4 of 6 3.3 Import: If importing of fill material is required for grading, proposed import material shall meet the requirements of Section 3.1. The potential import source shall be given to the Geotechnical Consuhant at least 48 hours (2 working days) before importing begins so that its suitability can be detennined and appropriate tests performed. 4.0 Fill Placement and Compaction 4.1 Fill Layers: Approved fill material shall be placed in areas prepared to receive fill (per Section 3.0) in near-horizontal layers not exceeding 8 inches in loose thickness. The Geotechnical Consultant may accept thicker layers if testing indicates the grading procedures can adequately compact the thicker layers. Each layer shall be spread evenly and mixed thoroughly to attain relative uniformity of material and moisture throughout. 4.2 Fill Moisture Conditioning: Fill soils shall be watered, dried back, blended, and/or mixed, as necessary to attain a relatively uniform moisture content at or slightly over optimum. Maximum density and optimum soil moisture content tests shall be performed in accordance with the American Society of Testing and Materials (ASTM Test Method D1557-91). 4.3 Compaction of Fill: After each layer has been moisture-conditioned, mixed, and evenly spread, it shall be uniformly compacted to not less than 90 percent of maximum dry density (ASTM Test Method D1557-91). Compaction equipment shall be adequately sized and be either specifically designed for soil compaction or of proven reliability to efficiently achieve the specified level of compaction with uniformity. 4.4 Compaction of Fill Slopes: In addition to normal compaction procedures specified above, compaction of slopes shall be accomplished by backrolling of slopes with sheepsfoot rollers at increments of 3 to 4 feet in fill elevation, or by other methods producing satisfactory results acceptable to the Geotechnical Consultant. Upon completion of grading, relative compaction of the fill, out to the slope face, shall be at least 90 percent of maximum density per ASTM Test Method Dl 557-91. 4.5 Compaction Testing: Field tests for moisture content and relative compaction of the fill soils shall be performed by the Geotechnical Consultant. Location and frequency of tests shall be at the Consultant's discretion based on field conditions encountered. Compaction test locations will not necessarily be selected on a random basis. Test locations shall be selected to verify adequacy of compaction levels in areas that are judged to be prone to inadequate compaction (such as close to slope faces and at the fill/bedrock benches). 3030.1094 Leightonand Associates,Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 5 of 6 4.6 Frequencv of Compaction Testing: Tests shall be taken at intervals not exceeding 2 feet in vertical rise and/or 1,000 cubic yards of compacted fill soils embankment. In addition, as a guideline, at least one test shall be taken on slope faces for each 5,000 square feet of slope face and/or each 10 feet of vertical height of slope. The Contractor shall assure that fill construction is such that the testing schedule can be accomplished by the Geotechnical Consultant. The Contractor shall stop or slow down the earthwork construction if these minimum standards are not met. 4.7 Compaction Test Locations: The GeotechnicalConsultantshall document the approximate elevation and horizontal coordinates of each test location. The Contractor shall coordinate with the project surveyor to assure that sufficient grade stakes are established so that the Geotechnical Consultant can determine the test locations with sufficient accuracy. At a minimum, two grade stakes within a horizontal distance of 100 feet and vertically less than 5 feet apart from potential test locations shall be provided. 5.0 Subdrain Installation Subdrain systems shall be installed in accordance with the approved geotechnical report(s), the grading plan, and the Standard Details. The Geotechnical Consultant may recommend additional subdrains and/or changes in subdrain extent, location, grade, or material depending on conditions encountered during grading. All subdrains shall be surveyed by a land surveyor/civil engineer for line and grade after installation and prior to burial. Sufficient time should be allowed by the Contractor for these surveys. 6.0 Excavation Excavations, as well as over-excavation for remedial purposes, shall be evaluated by the Geotechnical Consultant during grading. Remedial removal depths shown on geotechnical plans are estimates only. The actual extent of removal shall be determined by the Geotechnical Consultant based on the field evaluation of exposed conditions during grading. Where fill-over-cut slopes are to be graded, the cut portion of the slope shall be made, evaluated, and accepted by the Geotechnical Consultant prior to placement of materials for construction of the fill portion of the slope, unless otherwise recommended by the GeotechnicalConsultant 3030.1094 Leightonand Associates,Inc. GENERAL EARTHWORK AND GRADING SPECIFICATIONS Page 6 of 6 7.0 Trench Backfills 7.1 The Contractor shall follow all OHSA and Cal/OSHA requirements for safety of trench excavations. 7.2 All bedding and backfill of utility trenches shall be done in accordance with the applicable provisions of Standard Specifications of Public Works Construction. Bedding material shall have a Sand Equivalent greater than 30 (SE>30). The bedding shall be placed to 1 foot over the top of the conduit and densified by jetting. Backflll shall be placed and densified to a minimum of 90 percent of maximum from 1 foot above the top of the conduit to the surface. 7.3 The jetting of the bedding around the conduits shall be observed by the Geotechnical Consultant. 7.4 The Geotechnical Consultant shall test the trench backfill for relative compaction. At least one test should be made for every 300 feet of trench and 2 feet of fill. 7.5 Lift thickness of trench backflll shall not exceed those allowed in the Standard Specifications of Public Works Construction unless the Contractor can demonstrate to the Geotechnical Consultant that the fill lift can be compacted to the minimum relative compaction by his altemative equipment and method. 3030.1094 FILL SLOPE PROJECTED PLANE 1 TO 1 MAXIMUM FROM TOE OF SLOPE TO APPROVED GROUND EXISTING GROUND SURFACE i>'-'=^"-'-'->5C-X-'- BENCH HEIGHT (4' TYPICAL) REMOVE UNSUITABLE MATERIAL 2 MIN KEY DEPTH LOWEST BENCH (KEY) FILL-OVER-CUT SLOPE EXISTING GROUND SURFACE BENCH HEIGHT (4' TYPICAL) REMOVE UNSUITABLE MATERIAL CUT-OVER-FILL SLOPE OVERBUILD AND TRIM BACK -CUT FACE SHALL BE CONSTRUCTED PRIOR TO FILL PLACEMENT TO ASSURE ADEQUATE GEOLOGIC CONDITIONS EXISTING- GROUND SURFACE ^_.yy_^r^:. PROJECTED PLANE 1 TO 1 MAXIMUM FROM TOE OF SLOPE TO APPROVED GROUND CUT FACE SHALL BE CONSTRUCTED PRIOR TO FILL PLACEMENT REMOVE UNSUITABLE MATERIAL BENCH HEIGHT (4' TYPICAL) FOR SUBDRAINS SEE STANDARD DETAIL C 2" MIN.—I KEY DEPTH LOWEST BENCH (KEY) BENCHING SHALL BE DONE WHEN SLOPE'S ANGLE IS EQUAL TO OR GREATER THAN 5:1. MINIMUM BENCH HEIGHT SHALL BE 4 FEET AND MINIMUM FILL WIDTH SHALL BE 9 FEET KEYING AND BENCHING GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS A LEIGHTON AND ASSOCIATES FINISH GRADE SLOPE FACE » OVERSIZE ROCK IS LARGER THAN 8 INCHES IN LARGEST DIMENSION. • EXCAVATE A TRENCH IN THE COMPACTED FILL DEEP ENOUGH TO BURY ALL THE ROCK. * BACKFILL WITH GRANULAR SOIL JETTED OR FLOODED IN PLACE TO FILL ALL THE VOIDS. * DO NOT BURY ROCK WITHIN 10 FEET OF FINISH GRADE. • WINDROW OF BURIED ROCK SHALL BE PARALLEL TO THE FINISHED SLOPE. GRANULAR MATERIAL TO BE' DENSIFIED IN PLACE BY FLOODING OR JETTING. DETAIL -JETTED OR FLOODED GRANULAR MATERIAL TYPICAL PROFILE ALONG WINDROW OVERSIZE ROCK DISPOSAL GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS B LEIGHTON AND ASSOCIATES •s ^ EXISTING GROUND SURFACE BENCHING REMOVE UNSUITABLE MATERIAL CALTRANS CLASS 2 PERMEABLE . OR #2 ROCK (9FT''3/FT) WRAPPED IN FILTER FABRIC // SUBDRAIN TRENCH SEE DETAIL BELOW FILTER FABRIC (MIRAFI 140N OR APPROVED EQUIVALENT)* 4" MIN. BEDDING COLLECTOR PIPE SHALL BE MINIMUM 6" DIAMETER SCHEDULE 40 PVC PERFORATED PIPE. SEE STANDARD DETAIL D FOR PIPE SPECIFICATIONS SUBDRAIN DETAIL DESIGN FINISH GRADE FILTER FABRIC (MIRAFI MON OR APPROVED EQUIVALENT) CALTRANS CLASS 2 PERMEABLE OR #2 ROCK (9FT"3/FT) WRAPPED IN FILTER FABRIC NONPERFORATED 6"0 MIN PERFORATED 6" 0MIN. PIPE DETAIL QF CANYON SUBDRAIN OUTLET CANYON SUBDRAINS GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS C LEIGHTON AND ASSOCIATES 15' MIN. OUTLET PIPES 4" 0 NONPERFORATED PIPE, 100' MAX. O.C. HORIZONTALLY. 30' MAX O.C, VERTICALLY BACK CUT 1:1 OR FLATTER •SEE SUBDRAIN TRENCH DETAIL LOWEST SUBDRAIN SHOULD BE SITUATED AS LOW AS POSSIBLE TO ALLOW SUITABLE OUTLET -KEY DEPTH (2' MIN.) KEY WIDTH AS NOTED ON GRADING PLANS (15' MIN.) 12 MIN. OVERLAP — FROM THE TOP HOG RING TIED EVERY 6 FEET CALTRANS CLASS II PERMEABLE OR #2 ROCK (3 FT"3/FT) WRAPPED IN FILTER FABRIC ,-4" 0 \ NON-PERFORATED \ OUTLET PIPE PROVIDE POSITIVE SEAL AT THE JOINT T-CONNECTION FOR COLLECTOR PIPE TO OUTLET PIPE 6 MIN. COVER 4" 0 PERFORATED PIPE -FILTER FABRIC ENVELOPE (MIRAFI 140 OR APPROVED EQUIVALENT) 4 MIN. BEDDING SUBDRAIN TRENCH DETAIL SUBDRAIN INSTALLATION - subdroin collector pipe sholl be installed with perforation down or, unless otherwise designated by the geotechnicol consultont. Outlet pipes shall be non-perforated pipe. The subdroin pipe shall have ot least 8 perforations unifornnly spaced per foot. Perforotion shall be 1/4" to 1/2" if drill holes are used. All subdroin pipes shall have a gradient of at least 2% towards the outlet. SUBDRAIN PIPE - Subdrain pipe shall be ASTM D2751. SDR 23.5 or ASTM D1527, ASTM D3034, SDR 23.5. Schedule 40 Polyvinyl Chloride Plostic (PVC) pipe. Schedule 40, or All outlet pipe sholl be placed in a trench no wide thon twice the subdroin pipe. Pipe sholl be in soil of SE >/=30 jetted or flooded in place except for the outside 5 feet which shall be notive soil bockfill. BUTTRESS OR REPLACEMENT FILL SUBDRAINS GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS D LEIGHTON AND ASSOCIATES SOIL BACKFILL, COMPACTED TO 90 PERCENT RELATIVE COMPACTION BASED ON ASTM D1557 RETAINING WALL- WALL WATERPROOFING PER ARCHITECT'S SPECIFICATIONS WALL FOOTING- FILTER FABRIC ENVELOPE '(MIRAFI HON OR APPROVED EQUIVALENT)** -3/4" TO 1-1/2" CLEAN GRAVEL -4" (MIN.) DIAMETER PERFORATED PVC PIPE (SCHEDULE 40 OR EQUIVALENT) WITH PERFORATIONS ORIENTED DOWN AS DEPICTED MINIMUM 1 PERCENT GRADIENT TO SUITABLE OUTLET COMPETENT BEDROCK OR MATERIAL AS EVALUATED BY THE GEOTECHNICAL CONSULTANT NOTE: UPON REVIEW BY THE GEOTECHNICAL CONSULTANT, COMPOSITE DRAINAGE PRODUCTS SUCH AS MIRADRAIN OR J-DRAIN MAY BE USED AS AN ALTERNATIVE TO GRAVEL OR CLASS 2 PERMEABLE MATERIAL. INSTALLATION SHOULD BE PERFORMED IN ACCORDANCE WITH MANUFACTURER'S SPECIFICATIONS. RETAINING WALL DRAINAGE DETAIL GENERAL EARTHWORK AND GRADING SPECIFICATIONS STANDARD DETAILS E LEIGHTON AND ASSOCIATES