Rev 3, Geologic and Geotechnical Site Characterization Investigations for Nuclear Power Plants

ML21298A054
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Issue date:	12/31/2021
From:	Scott Stovall NRC/RES/DE/SGSEB
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ML21295A502	List: ML21298A059 Regulatory Guide 1.132
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DG-1392 RG 1.132 Rev 3
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U.S. NUCLEAR REGULATORY COMMISSION

REGULATORY GUIDE 1.132, REVISION 3 Issue Date: December 2021 Technical Lead: Scott Stovall GEOLOGIC AND GEOTECHNICAL SITE CHARACTERIZATION

INVESTIGATIONS FOR NUCLEAR POWER PLANTS

A. INTRODUCTION

Purpose This regulatory guide (RG) provides guidance on field investigations for determining the geologic, geotechnical, geophysical, and hydrogeologic characteristics of a prospective site for engineering analysis and design of nuclear power plants.

Applicability This RG applies to applicants and licensees subject to Title 10 of the Code of Federal Regulations

(10 CFR) Part 50, Domestic Licensing of Production and Utilization Facilities (Ref. 1),

10 CFR Part 52, Licenses, Certifications, and Approvals for Nuclear Power Plants (Ref. 2), and

10 CFR Part 100, Reactor Site Criteria (Ref. 3).

Applicable Regulations

• 10 CFR Part 50, Appendix A, General Design Criteria for Nuclear Power Plants, establishes minimum requirements for the principal design criteria for water-cooled nuclear power plants.

o General Design Criterion 2, Design Bases for Protection against Natural Phenomena, requires that structures important to safety be designed to withstand the effects of expected natural phenomena when combined with the effects of normal accident conditions without loss of capability to perform their safety function.

• 10 CFR Part 52, Licenses, Certifications, and Approvals for Nuclear Power Plants, governs the issuance of early site permits, standard design certifications, combined licenses, standard design approvals, and manufacturing licenses for nuclear power plants.

• 10 CFR Part 100, Reactor Site Criteria, requires the U.S. Nuclear Regulatory Commission (NRC) to consider population density; use of the site environs, including proximity to manmade hazards; and the physical characteristics of the site, including seismology, meteorology, geology, and hydrology, in determining the acceptability of a site for a nuclear power reactor.

Written suggestions regarding this guide or development of new guides may be submitted through the NRCs public Web site in the NRC Library at https://nrcweb.nrc.gov/reading-rm/doc-collections/reg-guides/, under Document Collections, in Regulatory Guides, at https://nrcweb.nrc.gov/reading-rm/doc-collections/reg-guides/contactus.html.

Electronic copies of this RG, previous versions of RGs, and other recently issued guides are also available through the NRCs public Web site in the NRC Library at https://nrcweb.nrc.gov/reading-rm/doc-collections/reg-guides/, under Document Collections, in Regulatory Guides. This RG is also available through the NRCs Agencywide Documents Access and Management System (ADAMS) at http://www.nrc.gov/reading-rm/adams.html, under ADAMS Accession Number (No.)

ML21298A054. The regulatory analysis may be found in ADAMS under Accession No. ML21194A177.

o 10 CFR 100 Subpart B, Evaluation Factors for Stationary Power Reactor Site Applications on or after January 10, 1997," provides the requirements for the factors to be considered.

Specific to this RG are 10 CFR 100.20(c), 100.21(d), and 100.23 that establish the requirements for conducting site investigations which include seismology, geology, meteorology, and hydrology.

Related Guidance

• NUREG-0800, Standard Review Plan for the Review of Safety Analysis Reports for Nuclear Power Plants: LWR Edition (Ref. 4), provides guidance to the NRC staff in performing safety reviews under 10 CFR Part 50 and 10 CFR Part 52. Chapter 2, Site Characteristics and Site Parameters, gives general review guidance related to site characteristics and site parameters, together with site-related design parameters and design characteristics, as applicable.

• RG 1.29, Seismic Design Classification for Nuclear Power Plants (Ref. 5), identifies the structures, systems, and components (SSCs) that should be designed to withstand the effects of the safe shutdown earthquake and remain functional.

• RG 1.70, Standard Format and Content of Safety Analysis Reports for Nuclear Power Plants:

LWR Edition (Ref. 6), and RG 1.206, Applications for Nuclear Power Plants (Ref. 7), provide general guidance on the types of information about the hydrologic setting and assessments of flooding hazards that a license application for a light-water reactor (LWR) power plant should include.

• RG 1.138, Laboratory Investigations of Soils and Rocks for Engineering Analysis and Design of Nuclear Power Plants (Ref. 8), provides guidance on sampling, storage, and laboratory investigations of the properties of soils for engineering analysis and design of nuclear power plants.

• RG1.201, Guidelines for Categorizing Structures, Systems, and Components in Nuclear Power Plants According to Their Safety Significance (Ref. 9), describes a risk-informed process for categorizing SSCs according to their safety significance that can remove SSCs of low safety significance from the scope of certain identified special treatment requirements.

• RG 4.7, General Site Suitability Criteria for Nuclear Power Stations (Ref. 10), assists applicants in the initial stage of selecting potential sites for a nuclear power station. The safety issues discussed include geological, seismic, hydrological, and meteorological characteristics of proposed sites as they relate to protecting the general public from the potential hazards of serious accidents.

Purpose of Regulatory Guides The NRC issues RGs to describe methods that are acceptable to the staff for implementing specific parts of the agencys regulations, to explain techniques that the staff uses in evaluating specific issues or postulated events, and to describe information that the staff needs in its review of applications for permits and licenses. Regulatory guides are not NRC regulations and compliance with them is not required. Methods and solutions that differ from those set forth in RGs are acceptable if supported by a basis for the issuance or continuance of a permit or license by the Commission.

RG 1.132, Page 2

Paperwork Reduction Act This RG provides voluntary guidance for implementing the mandatory information collections in

10 CFR Parts 50, 52, and 100 that are subject to the Paperwork Reduction Act of 1995 (44 U.S.C. 3501 et. seq.). These information collections were approved by the Office of Management and Budget (OMB),

approval numbers 3150-0011, 3150-0151, and 3150-0093 respectively. Send comments regarding this information collection to the FOIA, Library, and Information Collections Branch, (T6-A10M), U.S.

Nuclear Regulatory Commission, Washington, DC 20555-0001, or by e-mail to Infocollects.Resource@nrc.gov, and to the OMB reviewer at: OMB Office of Information and Regulatory Affairs (3150-0011, 3150-0151, 3150-0093), Attn: Desk Officer for the Nuclear Regulatory Commission,

725 17th Street, NW Washington, DC 20503; e- mail: oira_submission@omb.eop.gov.

Public Protection Notification The NRC may not conduct or sponsor, and a person is not required to respond to, a collection of information unless the document requesting or requiring the collection displays a currently valid OMB

control number.

RG 1.132, Page 3

TABLE OF CONTENTS

A. INTRODUCTION

............................................................................................................................... 1 Purpose...................................................................................................................................................... 1 Applicability ............................................................................................................................................. 1 Applicable Regulations ............................................................................................................................. 1 Related Guidance ...................................................................................................................................... 2 Purpose of Regulatory Guides .................................................................................................................. 2 Paperwork Reduction Act ......................................................................................................................... 3 Public Protection Notification................................................................................................................... 3

B. DISCUSSION

..................................................................................................................................... 6 Reason for Revision .................................................................................................................................. 6 Background ............................................................................................................................................... 6 Consideration of International Standards .................................................................................................. 6 Documents Discussed in Staff Regulatory Guidance ............................................................................... 7 C. STAFF REGULATORY GUIDANCE ............................................................................................... 8

1. General Requirements ....................................................................................................................... 8

2. Types of Data to Be Acquired........................................................................................................... 8

2.1 Geologic Characteristics ................................................................................................................. 8

2.2 Engineering Properties of Soils and Rocks ..................................................................................... 9

2.3 Ground Water Conditions ............................................................................................................... 9

2.4 Human-Induced Conditions ............................................................................................................ 9

2.5 Cultural and Environmental Considerations ................................................................................... 9

2.6 Related Considerations ................................................................................................................... 9

3. Evaluation of Previously Published Information, Field Reconnaissance, and Preliminary Assessment of Site Suitability .................................................................................................................................... 10

3.1 General .......................................................................................................................................... 10

3.2 Evaluation of Previously Published Information .......................................................................... 10

3.3 Field Reconnaissance .................................................................................................................... 11

3.4 Preliminary Assessment of Site Suitability ................................................................................... 11

4. Detailed Site Investigations ................................................................................................................ 11

4.1 General .......................................................................................................................................... 11

4.2 Surface Investigations ................................................................................................................... 12

4.3 Subsurface Investigations ............................................................................................................. 13 RG 1.132, Page 4

4.4 Borings and Exploratory Excavations........................................................................................... 14

4.5 Sampling ....................................................................................................................................... 15

4.6 Borrow Materials .......................................................................................................................... 17

4.7 Materials Unsuitable for Foundations ........................................................................................... 18

4.8 Transportation and Storage of Samples ........................................................................................ 18

4.9 In Situ Testing ............................................................................................................................... 18

4.10 Geophysical Investigations ......................................................................................................... 19

4.11 Logs of Subsurface Investigations .............................................................................................. 21

5. Ground Water Investigations .......................................................................................................... 21

6. Construction Mapping .................................................................................................................... 22

7. Support Functions ........................................................................................................................... 23

7.1 Surveying, Mapping, and Development of the GIS Database ...................................................... 23

7.2 Records, Sample Retention, and Quality Assurance ..................................................................... 23

D. IMPLEMENTATION

....................................................................................................................... 25 REFERENCES ........................................................................................................................................... 26 APPENDIX A ........................................................................................................................................... A-1 SPECIAL GEOLOGIC FEATURES AND CONDITIONS CONSIDERED IN OFFICE STUDIES AND

FIELD OBSERVATIONS (adapted from EM 1110-1-1804, U.S. ARMY CORPS OF ENGINEERS,

2001) ......................................................................................................................................................... A-1 APPENDIX B ........................................................................................................................................... B-1 SOURCES OF GEOLOGIC INFORMATION (adapted from EM 1110-1-1804, U.S. ARMY CORPS OF

ENGINEERS, 2001) ................................................................................................................................. B-1 APPENDIX C ........................................................................................................................................... C-1 METHODS OF SUBSURFACE EXPLORATION ................................................................................. C-1 APPENDIX D ........................................................................................................................................... D-1 SPACING AND DEPTH OF SUBSURFACE EXPLORATIONS FOR FOUNDATIONS OF SAFETY-

RELATED ENGINEERED STRUCTURES............................................................................................ D-1 APPENDIX E ........................................................................................................................................... E-1 APPLICATIONS OF SELECTED GEOPHYSICAL METHODS FOR DETERMINATION OF

ENGINEERING PARAMETERS ............................................................................................................ E-1 APPENDIX F............................................................................................................................................ F-1 IN SITU TESTING METHODS............................................................................................................... F-1 APPENDIX G ........................................................................................................................................... G-1 INSTRUMENTS FOR MEASURING GROUND WATER PRESSURE ............................................... G-1 RG 1.132, Page 5

B. DISCUSSION

Reason for Revision This revision of the guide (Revision 3) captures updates to the U.S. Army Corps of Engineers Engineer Manuals that provide guidance for the procedures in this RG. The manual changes are primarily modest updating of geophysical methods used for site exploration and characterization. In addition, RG 1.165, Identification and Characterization of Seismic Sources and Determination of Safe Shutdown Earthquake Ground Motion, was withdrawn in 2010 and replaced by RG 1.208, A Performance-Based Approach to Define the Sites-Specific Earthquake Ground Motion (Ref. 11).

Background Site investigations are needed to define site-specific geologic, geotechnical, geophysical, and hydrogeologic characteristics to the degree necessary for understanding surface and subsurface conditions and identifying potential geologic hazards that might affect the site. Investigations for geologic hazards such as fault deformation, landslides, cavernous rocks (surface or subsurface karst), ground subsidence, soil liquefaction, and any other natural or manmade external hazards are of particular importance. The density of data collected will depend on variability of the soil and rock materials and the safety-related importance of structures planned for a particular site location. Well-conducted site investigations can save time and money by reducing problems in licensing and construction.

The site investigations described in this RG are closely related to those in RG 1.208. The main purpose of that RG is to define the site-specific, performance-based ground motion response spectrum in order to determine the safe-shutdown earthquake ground motion based on information derived from geologic, geotechnical, geophysical, and seismic investigations. Appendix C, Investigations to Characterize Site Geology, Seismology and Geophysics, to RG 1.208 gives guidance on the appropriate information needed to identify and characterize seismic source zone parameters and assess the potential for surface fault rupture and associated deformation at the site for use in probabilistic seismic hazard analyses.

It is worthwhile to point out that good site investigations have the added benefit of saving time and money by reducing problems in licensing and construction. A case study report on geotechnical investigations by the National Research Council (Ref. 12), for example, concludes that additional geotechnical information would almost always save time and costs.

Consideration of International Standards The International Atomic Energy Agency (IAEA) works with member states and other partners to promote the safe, secure, and peaceful use of nuclear technologies. The IAEA develops Safety Requirements and Safety Guides for protecting people and the environment from harmful effects of ionizing radiation. This system of safety fundamentals, safety requirements, safety guides, and other relevant reports reflects an international perspective on what constitutes a high level of safety. To inform its development of this RG, the NRC considered IAEA Safety Requirements and Safety Guides under the Commissions International Policy Statement (Ref. 13) and Management Directive 6.6, Regulatory Guides (Ref. 14).

The NRC staff considered the following IAEA safety requirements and guides in the development/update of this RG:

RG 1.132, Page 6

• IAEA Safety Standards Series No. NS-G-3.6, Geotechnical Aspects of Site Evaluation and Foundations for Nuclear Power Plants, issued 2005 (Ref. 15)

• IAEA Specific Safety Guide No. SSG-9, Seismic Hazards in Site Evaluation for Nuclear Installations, issued 2010 (Ref. 16)

Documents Discussed in Staff Regulatory Guidance This RG endorses the use of one or more codes or standards developed by external organizations, and other third-party guidance documents. These codes, standards, and third-party guidance documents may contain references to other codes, standards or third party guidance documents (secondary references). If a secondary reference has itself been incorporated by reference into NRC regulations as a requirement, then licensees and applicants must comply with that standard as set forth in the regulation. If the secondary reference has been endorsed in a RG as an acceptable approach for meeting an NRC

requirement, then the standard constitutes a method acceptable to the NRC staff for meeting that regulatory requirement as described in the specific RG. If the secondary reference has neither been incorporated by reference into NRC regulations nor endorsed in a RG, then the secondary reference is neither a legally-binding requirement nor a generic NRC approved acceptable approach for meeting an NRC requirement. However, licensees and applicants may consider and use the information in the secondary reference, if appropriately justified, consistent with current regulatory practice, and consistent with applicable NRC requirements.

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C. STAFF REGULATORY GUIDANCE

1. General Requirements A well-planned program of site exploration should be conducted using a phased approach that progresses from a literature search and reconnaissance investigations to detailed site investigations, construction mapping, and final as-built data compilation to provide a strong basis for site suitability determination and foundation design and construction. The actual site investigation program should be tailored to the specific conditions of the site and based on sound professional judgment. The site investigation program should be flexible and modified when needed, as the site investigation proceeds based on the provisions and criteria of the project.

Site investigations for nuclear power plants should be adequate in terms of thoroughness, suitability of methods used, quality of execution of the work, and documentation to permit an accurate determination of the geologic and geotechnical conditions that affect the design, performance, and safety of the plant. The investigations should provide information needed to perform engineering analyses and design the plant with reasonable assurance that the geologic and geotechnical conditions and associated uncertainties have been appropriately determined and considered.

This guide considers techniques available at the date of issuance. As science advances, useful procedures, standards, and equipment should be included as they are developed and accepted by the profession.

2. Types of Data to Be Acquired

2.1 Geologic Characteristics Geologic characteristics include, but are not limited to, the following:

• Lithology and other distinguishing features of rock units at the surface and in the subsurface.

Depositional and tectonic deformation features include bedding planes, faults and shear zones, joints, and foliation surfaces, the orientations of which are needed for characterization of the features.

• Nature, degree, and extent of weathering at the surface and in the shallow subsurface.

Weathering-related characteristics include soil type, presence of expanding soils, and karst features that are active or relict (sinkholes and dolines, disappearing streams, caverns, and subsurface voids not detectable at the surface).

• Potential for soil liquefaction and evidence for paleoliquefaction.

• Natural hazards that include seismic events, surficial and blind faults, landslide potential, nontectonic deformation, susceptibility to erosion, sea level rise, flooding, tsunami, seiche, and storm wave action.

Appendix A to this guide lists special geologic features and conditions that might need to be investigated during site characterization, either as office-based or field studies.

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2.2 Engineering Properties of Soils and Rocks Engineering properties of soil and rock include static and dynamic properties such as density, moisture content, strength parameters, elasticity, plasticity, hydraulic conductivities, rock joint characteristics, seismic velocities, and degradation properties associated with strain. Some of these properties can be measured in situ, and those measurements, together with sample collection methods, are discussed in this guide. Determination of these and other engineering properties also requires laboratory testing, which is described in RG 1.138.

2.3 Ground Water Conditions Ground water conditions that can impact the engineering design, performance, and durability of the foundations and structures should be determined. These conditions include ground water levels, chemical properties of ground water, thickness and extent of aquifers and confining beds, ground water flow patterns, recharge areas, discharge points and transmissivities, and storage coefficients.

2.4 Human-Induced Conditions Existing infrastructure should be located, including dams or reservoirs that might cause a flooding hazard or induce loading effects at the site. Past or ongoing activities, such as mining, oil and gas production to include hydrofracking, and other fluid extraction or injection activities, should be assessed and documented. The presence of former or current industrial sites, underground storage tanks, abandoned well casings, buried foundations, conduits, pipes, sumps, or landfills should be identified. The potential for hazardous, toxic, or radioactive waste should also be investigated and documented.

2.5 Cultural and Environmental Considerations Assessment for cultural resources, such as archaeological sites and artifacts, must comply with the Archaeological Resources Protection Act of 1979 and the Native American Graves Protection and Repatriation Act of 1990.

The National Historic Preservation Act (36 CFR Part 800, Protection of Historic Properties)

must be considered if the site investigation will affect historic property. Under that condition, the Section 106 review process must be followed.

Aspects of the Clean Water Act (33 U.S.C. 1344) must be taken into account. Placement of fill in wetlands is regulated at the national level, and State and local wetland protection laws may also apply.

The Corps of Engineers Wetlands Delineation Manual (Ref. 17) gives guidance on identifying and delineating wetlands. Information on applications for Section 404 permits for modifying wetlands can be obtained from District Offices of the Army Corps of Engineers.

2.6 Related Considerations RG 1.208 provides guidance on seismicity and related seismic data and historical records, together with guidance on determination of vibratory ground motion resulting from earthquakes. Many of the investigations listed in RG 1.208 could and should be coordinated with the site investigations described in this guide and conducted at the same time for greater efficiency. Appendix C to RG 1.208 should be used as guidance for investigating tectonic and nontectonic surface deformation.

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3. Evaluation of Previously Published Information, Field Reconnaissance, and Preliminary Assessment of Site Suitability

3.1 General Establishing the geologic characteristics and engineering properties of a site is an iterative process during which successive phases of investigation produce increasingly detailed data. Therefore, it is important to have a proper system for recording the data and gaining a three-dimensional spatial understanding of site conditions.

A geographic information system (GIS) database is an efficient way to collect and present spatial data. A well-planned database system for compiling pertinent data is important for data retrieval and analysis and is a part of the quality assurance requirements for a project (see Regulatory Position 7.2).

RG 1.208 indicates that geologic, seismic, and geophysical investigations are to be performed to develop an up-to-date, site-specific, geoscience database that supports the site characterization efforts.

3.2 Evaluation of Previously Published Information The first step in the site investigation process is to acquire and evaluate existing data related to geologic characteristics and engineering properties of the site. Information about regional geology should be considered to assist with understanding rock and soil properties of the site in the proper regional context. Reconnaissance-level investigations can start with review of published reports, data, and existing maps illustrating topography, geology, hydrology, previous land use and construction, and infrastructure.

Study of aerial photographs, satellite imagery, light detection and ranging (LiDAR) surveys, and other remote sensing imagery can be used to complement this information. If available, regional strain rates measured using the Global Positioning System (GPS) (Ref. 18) should be collected to correlate with strain rates obtained from geologic data and other data sets.

Possible sources of current and historical documentary information could include the following:

• geology and engineering departments of State and local universities;

• county governments, many of which have GIS data of various kinds available;

• State government agencies, such as State geological surveys;

• U.S. government agencies, such as the U.S. Geological Survey, the Bureau of Reclamation, and the U.S. Army Corps of Engineers;

• newspaper records of earthquakes, floods, landslides, and other natural events of significance;

• interviews with local inhabitants and knowledgeable professionals; and

• reputable and relevant online documents.

Appendix B to this guide lists additional potential sources for maps, imagery, and other pertinent geologic data.

For license applications for a site near an existing nuclear power plant with a similar geologic setting, documents related to the site investigation for the existing plant could provide valuable information. Plans held by utilities should be consulted to locate services such as water, gas, electric, and RG 1.132, Page 10

communication lines. Locations of power lines, pipelines, and access routes should be established.

Mining records should be consulted to determine locations of abandoned adits, shafts, mining works, benches, and tailings ponds and embankments. Oil, gas, and water well records and oil and gas field exploration data can provide valuable subsurface information. Historical and archaeological sites should be identified to document locations of potential cultural resources.

3.3 Field Reconnaissance In addition to evaluating and documenting previously published information, it is necessary to perform preliminary field reconnaissance of the site and the surrounding area. This step enables an assessment of field data related to site conditions and regional geology and establishes the basis for a detailed site investigation plan. Appendix A to this guide lists special geologic features and conditions that should be considered. In addition to site-specific conditions, areas containing potential borrow sources, quarry sites, and water impoundments should be investigated.

The team performing the reconnaissance should include, as a minimum, a geologist and a geotechnical engineer and could also include other specialists (e.g., an engineering geologist or geophysicist). Appropriate topographic and geologic maps should be used during the field reconnaissance, if available, to locate features of potential interest. A GPS unit would be advantageous for recording locations in the field, as noted in more detail in Regulatory Position 7.1.

3.4 Preliminary Assessment of Site Suitability After completion of the field reconnaissance investigations and in conjunction with the information in the developed database, a preliminary determination of site suitability should be made to identify information gaps and potential hazards to help formulate the plan for the detailed site investigation stage. The presence of features or characteristics that could potentially result in deleterious ground displacement (e.g., fault displacement, subsurface dissolution, and settlement or subsidence),

swelling soils and shales, or other natural hazards (e.g., underground cavities, landslides, or periodic flooding) could make plant design difficult and require additional extensive investigations to assess properly. For sites where such features and characteristics exist, it might be advantageous to search for a more suitable site.

4. Detailed Site Investigations

4.1 General The detailed site investigation phase acquires all geologic and material property data needed for the engineering analyses, design, and construction of a plant, including the related critical structures. A

multidisciplinary team is needed to accomplish the different tasks during this phase. Subsequent site investigations might be needed if additional data are required to supplement a gap in the knowledge associated with the geologic characteristics and subsurface material properties at the site.

The engineering properties of rock and soil can be determined through drilling and sampling, in situ testing, field geophysical measurements, and laboratory testing. This guide describes in situ testing and field geophysical measurements, as well as drilling and sampling procedures used to gather samples for laboratory testing. For guidance on laboratory testing procedures, refer to RG 1.138.

All pertinent conclusions should be presented and linked directly to the information that provides the bases for the conclusions. Site-specific information to be developed and analyzed should include, but not be limited to, the following:

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(1) Topographic and geologic maps. The geologic maps should show rock types and locations of tectonic and nontectonic geologic features, as well as points where field samples were collected for laboratory analysis (e.g., for radiometric age dating and determination of material properties).

(2) Plot plans showing the locations of major anticipated engineered structures and points at which site investigation tests were conducted and data or measurements were collected.

(3) Boring logs and geologic logs of exploratory trenches and excavations.

(4) Geologic profiles illustrating subsurface geology and excavation limits for engineered structures.

(5) Geophysical information such as survey lines, seismic survey time-distance plots, resistivity curves, seismic reflection and refraction plots, seismic wave velocity profiles, surface wave dispersion plots, and borehole loggings.

Locations of all boreholes, ground water observation wells and piezometers, in situ tests, trenches, exploration pits, and geophysical measurements should be surveyed in both plan and elevation.

This three-dimensional information should be entered into a GIS database. Suitable cross sections, maps, and plans should be prepared to facilitate visualization of the geologic information. Regulatory Position 7.1 gives further details.

Detailed site investigations should use applicable industrial standards for specific techniques, methods, and procedures. Regulatory Position 7.2 provides quality assurance requirements. Use of investigative and sampling techniques other than those discussed in this guide is acceptable when it can be shown that the alternative techniques yield satisfactory results.

4.2 Surface Investigations Detailed surface geologic and geotechnical engineering investigations should be conducted over the site area to assess all pertinent soil and rock characteristics. The definition of site area, as specified in RG 1.208, is that area within a radius of 8 kilometers (5 miles) of the site. Appendix A to this guide lists some of the special geologic features and conditions to be considered.

The initial step in conducting detailed surface investigations for a site is to prepare three-dimensional topographic maps at a scale suitable for plotting the geologic features and characteristics and showing features in the surrounding area that are related, for example, to borrow areas, quarries, and access roads. Aerial photographs and stereoscopic image pairs, other remote sensing imagery (e.g., satellite imagery and LiDAR), and the results of geophysical surveys are valuable for regional analysis, determination of fault and fracture patterns, location of potential nontectonic surficial features related to possible subsurface dissolution, and other features of interest.

Depending on the site, detailed mapping of the following site characteristics and associated features should be considered during conduct of the surface investigations:

• topography (including geomorphic features, lineaments, paleo-landslides, closed depressions, river terraces, and alluvial and glacial deposits),

• hydrology (including rivers, streams, lakes, wetlands, local drainage channels, springs, and sinkholes),

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• geology (including outcrops; tectonic features such as faults, shear zones, and zones exhibiting strong fracturing or alteration; nontectonic features such as surficial indicators of subsurface dissolution; rock unit contacts), and

• engineering geology (including soil conditions and soil types, chemically or physically weathered zones and horizons, and areas exhibiting material properties conducive to soil liquefaction).

All maps produced should include standard map labels such as scales, a north arrow, map projection information, title, and citation of original data or data sources.

4.3 Subsurface Investigations Subsurface investigations expand knowledge of the three-dimensional distribution of geologic features and characteristics and geotechnical engineering properties at the site and in borrow areas.

Subsurface investigations also provide information on potential natural hazards such as nontectonic underground features (e.g., dissolution cavities), hidden faults, soft zones, or geologic contacts. The investigations should use a variety of appropriate methods, including borings and excavations augmented by geophysical measurements and geophysical surveys. Appendix C to this guide tabulates methods of conducting subsurface investigations. Techniques employing different measurement approaches should be used to determine geologic conditions and geotechnical engineering properties to account for uncertainties in the data and to cross-check the conformability and reasonableness of the data obtained during site investigations. An adequate number of tests for each method should be performed to quantify the mean and variability of pertinent site parameters and geotechnical engineering properties of subsurface materials.

Locations and depths of borings, excavations, and geophysical measurements should be selected such that site-specific geology and foundation support conditions are sufficiently defined in both lateral extent and depth to permit the suitable design of all necessary excavations and engineered structures. The information acquired should also support development of geologic cross sections and subsurface profiles that contain field testing data (e.g., N-values, cone penetration test values, and seismic wave velocities)

constructed through the foundations of safety-related structures and other important structures at the site.

Subsurface investigations for less critical foundations of power plants should be carried out at a spacing and depth of penetration necessary to define the geologic conditions and geotechnical engineering properties of the subsurface materials. Subsurface investigations in areas remote from plant foundations might be needed to complete the geologic description and confirm the geologic conditions of the site.

Subsurface investigations for materials to be used for backfill, improvement of subsurface conditions, or ground water control under the foundations of safety-related structures, including granular and nongranular materials, should be performed to confirm that stability and durability requirements will be met and to validate the material properties to be used for design and analysis.

Boreholes are one effective way to obtain detailed information on subsurface geologic conditions and the engineering properties of subsurface materials. Core and other samples recovered from boreholes, geophysical and borehole surveys, and other in situ borehole tests can provide important subsurface information. Test pits, trenches, and exploratory shafts can be used to complement the borehole exploration results; provide additional detailed information on rock and soil conditions, faulting, and density of in situ materials; and obtain high-quality undisturbed samples.

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4.4 Borings and Exploratory Excavations Field operations conducted at the site should be supervised by experienced personnel familiar with site operations, and systematic standards of practice should be followed. Procedures and equipment used to carry out field operations, including necessary calibrations, and all conditions encountered in various phases of the investigations should be documented. Personnel who are experienced and thoroughly familiar with sampling and testing procedures should inspect and document sampling results and transfer samples from the field to storage or laboratory facilities with a properly executed chain-of-custody record.

The complexity of geologic conditions and foundation requirements should be considered in choosing the distribution, number, and depth of borings and other excavations at the site. The investigative efforts should be greatest at the locations of safety-related structures and might vary in density and scope in other areas according to spatial and geologic relationships to the specific site.

Excavation trenches across faults or shear zones might be required to determine the age of last movement on these tectonic features to better assess the potential impact of the features on site safety. At least one continuously sampled boring should be drilled for each safety-related structure, and the boring should extend to a depth sufficient for defining the geologic and hydrogeologic characteristics of the subsurface materials that will influence the stability and suitability of the safety-related structures.

NUREG/CR-5738, Field Investigations for Foundations of Nuclear Power Plants, issued November 1999, describes procedures for borings and exploratory excavations. Appendix C to this guide reproduces a table from NUREG/CR-5738 showing widely used techniques for subsurface investigations and describing the applicability and limitations of the techniques. Appendix D to this RG contains general guidelines for spacing and depth of borings.

4.4.1 Spacing and Depth Spacing, depth, and the number of borings for safety-related structures should be chosen and justified based on foundation requirements and the complexity of anticipated subsurface conditions.

Appendix D provides general guidelines on this topic. Spacing of borings for a deeply embedded structure with smaller foundation dimensions should be reduced, and additional boreholes should be located outside the foundation footprint to obtain detailed geologic and geotechnical information about the surrounding materials. This information will provide pertinent data for the analysis of soil-structure interactions and determination of lateral earth pressures.

Uniform subsurface conditions permit the maximum spacing of borings in a regular grid for adequate definition of those conditions. Subsurface conditions can be considered uniform if the geologic characteristics and features to be defined can be correlated from one boring location to the next with relatively smooth variations in thicknesses and properties of the geologic units. An occasional anomaly or a limited number of unexpected lateral variations might occur.

If subsurface conditions are not uniform, a regular grid might not provide the most effective distribution of boreholes. Soil deposits or rock units could be encountered in which the geologic characteristics are so complex that only the major rock unit contacts are correlated. Material types and properties might also vary within major geologic units in an apparently random manner from one boring to another. The number and distribution of borings needed for such nonuniform conditions are determined by the degree of resolution needed to define geotechnical properties required for engineering design. In locations with sedimentary rock formations, it will be helpful to understand the environment of deposition for the various geologic units at the site in order to understand lateral and vertical variations within the units. The goal of the investigations is to define the thicknesses of the different subsurface materials, RG 1.132, Page 14

degree of lateral and vertical variability of the materials, and the range of geologic characteristics and geotechnical properties of the materials that underlie all major structures.

If there is evidence suggesting the presence of local adverse anomalies or discontinuities in the subsurface (e.g., cavities, sinkholes, fissures, faults, brecciated zones, lenses, or pockets of unsuitable material), then supplementary borings at a spacing small enough to detect and delineate these features are needed. At locations with limestone, dolostone, and anhydrite, the size, frequency, and depth of voids or caverns should be considered because different mechanisms or dissolution processes may exist. It is important that the supplementary borings penetrate all potentially detrimental zones or extend to depths below which presence of these zones would not influence stability of the structures. Geophysical investigations should be used together with the borings to better characterize subsurface conditions at the site.

4.4.2 Drilling Procedures Drilling methods and procedures should be compatible with sampling requirements and the methods of sample recovery. Many of the methods are discussed in detail in U.S. Army Corps of Engineers Engineer Manual (EM) 1110-1-1804, Geotechnical Investigations, issued 2001 (Ref. 19).

The top of the borehole should be protected by a suitable surface casing where needed. Below ground surface, the borehole should be protected by drilling mud or casing, as necessary, to prevent caving and disturbance of materials to be sampled. The use of drilling mud is preferred to prevent disturbance when obtaining undisturbed samples of coarse-grained soils. However, casing may be used if proper steps are taken to prevent disturbance of the soil being sampled and to prevent upward movement of soil into the casing. After use, each borehole should be grouted in accordance with State and local codes to prevent vertical movement of ground water through the borehole.

Borehole elevation and depths into the ground should be measured to the nearest 3 centimeters

(0.1 foot) and should be correlated with the elevation datum used for the site. Surveys of vertical deviation should be run in all boreholes that are used for in situ seismic tests (e.g., crosshole, downhole, compression wave-shear wave (P-S) suspension logging) and other tests where deviation potentially affects the data obtained. Boreholes with depths greater than about 30 meters (100 feet) should also be surveyed for deviation. Regulatory Position 4.5 details the information that should be presented in logs of subsurface investigations.

Except where the borehole is being preserved for future use, all boreholes and exploratory excavations should be backfilled. Many States have requirements about backfilling boreholes. Therefore, appropriate State officials should be consulted. Borings that are preserved for future use should be protected with a short section of surface casing, capped, and identified.

4.5 Sampling Suitable samples of rock and soil should be obtained for identification and classification, mechanical analyses, and anticipated laboratory testing. The need for, number, and distribution of samples will depend on testing requirements and the variability of the field conditions. A sufficient number of samples should be collected to meet the needs of laboratory testing, especially when undisturbed samples are required. It is important to obtain good-quality undisturbed samples for cyclic load testing. In general, soil and rock samples should be collected from more than one principal boring within the foundation support zone of each safety-related structure.

Sampling of soil and rock in boreholes should include, as a minimum, recovery of samples at regular intervals and where changes in materials occur. One or more borings for each major structure RG 1.132, Page 15

should be continuously sampled. Proper sampling methods should be used to collect soil samples.

Standard penetration and cone penetration tests should be used with sufficient coverage to define the soil profile and variations in soil conditions. Alternating split spoon and undisturbed samples with depth is recommended for soil samples. Color photographs of all cores should be taken soon after removal from the borehole to document the condition of subsurface materials at the time of drilling. For a deeply embedded structure, sampling intervals should be properly determined and detailed field testing should be carried out along the length of the embedded portion of the structure to obtain sufficient geologic and geotechnical information.

4.5.1 Sampling Rock The engineering characteristics of the rock mass are related primarily to composition and geologic features of the rock units, including bedding planes, joints, fractures, orientation, position, length and spacing of any other geologic discontinuities, surface infilling, and weathering. Rock outcrops may be one of the information sources necessary for rock mass characterization, especially for structures that require relatively shallow excavations. Core samples can also provide reliable information to define the engineering characteristics of the rock mass. Suitable coring methods should be employed, and rocks should be sampled to a depth below which rock characteristics do not influence foundation performance.

Deeper borings may be needed to investigate zones critical to the evaluation of site geologic conditions. Within the depth intervals influencing foundation performance, zones of poor core recovery or low rock quality designation, zones requiring casing, and other zones where drilling difficulties are encountered should be investigated. The nature, geometry, and spacing of any discontinuities or anomalous zones should be determined by means of suitable logging or in situ observation methods, such as an in-hole camera or televiewer. Areas with evidence of significant residual stresses should be evaluated based on in situ stress or strain measurements. Dip and strike of bedding planes and joints in the near-surface region can be measured at the outcrop. However, oriented cores are needed to estimate dips and strikes at depth.

A sufficient number of samples of both intact rock and jointed rock mass should be collected for strength property testing. The parameters developed from the rock mass characterization program provide input to different rock mass classification schemes (e.g., Rock Mass Rating system, Q system, Geological Strength Index system). The quality of the rock mass, estimated using the classification schemes, may be used in empirical design methods of rock excavation.

4.5.2 Sampling Coarse-Grained Soils For coarse-grained soils, samples should be taken at depth intervals no greater than 1.5 meters

(5 feet). Beyond a depth of 15 meters (50 feet) below foundation level, the depth interval for sampling may be increased to 3 meters (10 feet). Requirements for undisturbed sampling of coarse-grained soils will depend on actual site conditions and planned laboratory testing. Experimentation with different sampling techniques may be necessary to determine the method that is best suited to local soil conditions.

Coarse-grained soils containing gravels and boulders are among the most difficult materials to sample. Obtaining good-quality samples often requires the use of trenches, pits, or other accessible excavations into the zones of interest. Standard penetration test results from these materials may be misleading and must be interpreted very carefully. When sampling of coarse soils is difficult, information that may be lost when the soil is later classified in the laboratory should be recorded in the field. This information should include observed estimates of the percentage of cobbles, boulders, and coarse material and the hardness, shape, surface coating, and degree of weathering of coarse materials.

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4.5.3 Sampling Moderately Compressible or Normally Consolidated Clay or Clayey Soils The properties of a fine-grained soil are related to the in situ structure of the soil, and undisturbed samples should be obtained. Regulatory Position 4.5.4 of this guide discusses procedures for obtaining undisturbed samples.

For compressible or normally consolidated clays, undisturbed samples should be continuous throughout the compressible strata in one or more principal borings. These samples should be obtained by means of suitable fixed-piston, thin-wall tube samplers (see Appendix F to EM 1110-1-1804 for detailed procedures) or by methods that yield samples of equivalent quality. Borings used for undisturbed sampling of soils should be at least 7.6 centimeters (3 inches) in diameter.

4.5.4 Obtaining Undisturbed Samples In a strict sense, it is physically impossible to obtain undisturbed samples in borings because of the adverse effects resulting from the sampling process (e.g., unloading caused by removal from confinement) and from shipping or handling. Undisturbed samples are normally obtained using one of two general methods: push samplers or rotary samplers. These methods permit obtaining satisfactory samples for shear strength, consolidation, permeability, and density tests, provided careful measurements are made to document volume changes that occur during each step in the sampling process. Undisturbed samples can be sliced to permit detailed study of subsoil stratification, joints, fissures, failure planes, and other details. Guidance on commonly used undisturbed sampling methods can be found in relevant America Society for Testing and Materials (ASTM) standards.

Undisturbed samples of clays and silts can be obtained, as well as nearly undisturbed samples of some sands. Care is necessary in transporting any undisturbed sample, and sands and silts are particularly vulnerable to vibration disturbance. One method to prevent handling disturbance is to obtain

7.6-centimeter (3-inch) Shelby tube samples, drain them, and freeze them before transportation. The commonly used general procedure for recovering cohesionless soil is to stabilize the soil, extract the sample, and later remove (reverse) the stabilizing agent after transportation, then trim and confine the specimen in a testing device. Reversible stabilization methods include the biopolymers agar and agarose, Elmers glue, and freezing. These stabilization methods must be durable enough to allow handling, transportation, and trimming of the samples. The methods also need to be reversible so that cohesionless soil can be restored to its in situ state before laboratory testing for evaluation of stress-stain-strength properties. Disturbance associated with these methods, such as volume changes in the soil and pore water when using chemical or biochemical solutions or by cryogenic effects, must be taken into account.

Test pits, trenches, and shafts offer the only effective access for collecting high-quality undisturbed samples and obtaining detailed information on stratification, discontinuities, or preexisting shear surfaces. Cost increases with penetration depth as the need for sidewall support arises. Samples can be obtained by hand-carving oversized blocks of soil or hand-advancing thin-walled tubes.

4.6 Borrow Materials Exploration for borrow sources determines the location and amount of available borrow materials. Borrow area investigations should consider horizontal and vertical intervals sufficient to determine material variability and include adequate sampling of representative materials for laboratory testing. Exploration of borrow sources should be tied to performance requirements expected from the backfill. It is preferable that one source or quarry be selected as a candidate for supplying all project fill material when possible; otherwise, the number of candidate borrow sources or quarries should be minimized for optimum quality assurance and quality control. The quantity of samples required should be RG 1.132, Page 17

determined based on the type and number of tests planned. A sufficient quantity of each fill type should be collected, preferably all during the initial sampling efforts, to ensure better uniformity in soils collected and sampling methods.

4.7 Materials Unsuitable for Foundations Boundaries of unsuitable materials should be delineated by borings and representative sampling and testing. These boundaries should be used to define the required excavation limits.

4.8 Transportation and Storage of Samples Handling, storage, and transportation of samples are as critical for sample quality as the collection procedures used. Disturbance of samples after collection can happen in a variety of ways and transform samples from high quality to slightly disturbed to unusable. Soil samples can change dramatically because of moisture loss, moisture migration within the sample, freezing, vibration, shock, or chemical reactions.

Moisture loss might not be critical on representative samples but should be kept to a minimum.

Moisture migration within a sample can cause differential residual pore pressure to equalize with time.

Water can move from one layer to another, causing significant changes in the undrained strength and compressibility of the sample. Freezing of clay or silt samples can cause ice lenses to form and severely disturb the samples. Therefore, storage room temperatures for clay and silt samples should be kept above

4 degrees Celsius (C). Vibration or shock can provoke remolding and strength or density changes, especially in soft and sensitive clays, and cohesionless samples. Transportation should be carefully arranged to avoid such effects. Chemical reactions between samples and sample containers can occur during storage and induce changes that affect soil plasticity, compressibility, and shear strength.

Therefore, selection of the correct sample container material is important.

Unless stabilized chemically or by freezing, cohesionless soil samples are particularly sensitive to disturbance from impact and vibration during removal from the borehole or sampler and subsequent handling. Samples should (1) be kept in the same orientation as that in which the samples were taken at all times (e.g., in a vertical position if sampled in a vertical borehole), (2) be well padded for isolation from vibration and impact, and (3) be transported with extreme care if undisturbed samples are required.

4.9 In Situ Testing In situ testing of soil and rock materials should be conducted where necessary for definition of subsurface material properties and in situ state of stress using boreholes, excavations, test pits, and trenches that are either available or have been prepared for sampling and testing. Larger block samples for laboratory testing can also be obtained at the same locations. Appendix F to this guide shows some applicable in situ testing methods. NUREG/CR-5738 further describes the procedures.

In situ tests are often the best means to determine the engineering properties of subsurface materials and, in some cases, might be the only way to obtain meaningful results. Some materials are hard to sample and transport while keeping them representative of field conditions, because of softness, lack of cohesion, or composition. In situ testing techniques offer a valuable option for evaluating soils and rocks that cannot be sampled for laboratory analysis.

Interpretation of in situ test results in soils, clay-rich shales, and moisture-sensitive rocks requires consideration of the drainage that may occur during the test. Consolidation during soil testing makes it difficult to determine whether the results relate to unconsolidated-undrained, consolidated-undrained, consolidated-drained, or unconsolidated-drained conditions or to intermediate conditions between these RG 1.132, Page 18

limiting states. Interpretation of in situ test results requires the complete evaluation of test conditions and limitations.

Rock units commonly contain natural joints, bedding planes, or other discontinuities (e.g., faults and shear zones) that result in irregularly shaped blocks that respond as a discontinuum to various loading conditions. Individual solid blocks might have relatively high compressive and shear strengths, whereas strength along the discontinuity surfaces can be significantly lower and highly anisotropic. Commonly, little or no tensile strength exists across discontinuities. Large-scale in situ tests tend to average out effects of the complex interactions between intact rock blocks and discontinuities. In situ tests in rock are used to determine in situ stresses and deformation properties, including strength and deformation modulus of the jointed rock mass. These tests also help to determine strength and residual stresses along discontinuities in the rock mass. In situ testing performed in weak, near-surface rocks includes penetration tests, plate loading tests, pressure-meter tests, and field geophysical tests.

Table F-2 in Appendix F lists in situ tests that are useful for determining the shear strength of subsurface materials. Direct shear-strength tests in rock measure peak and residual direct shear strength as a function of normal stress on the shear plane. Direct shear strength from intact rock can be measured in the laboratory if the specimen can be cut and transported without disturbance. In situ shear tests are discussed and compared by Nicholson (1983; Ref. 20) and Bowles (1996; Ref. 21). The suggested in situ method for determining direct shear strength of rocks is described in RTH 321-80, Suggested Method for In Situ Determination of Direct Shear Strength (ISRM), issued 1980 (Ref. 22). Although the standard penetration test (SPT) is used extensively in investigations of soil liquefaction susceptibility, the cone penetration test (CPT) is also widely used in site investigation because (1) the CPT provides continuous penetration resistance profiles for soils and (2) CPT results are more repeatable and consistent (Ref. 23).

Both Appendix C and Appendix F compare the applicability and limitations of the CPT and SPT.

4.10 Geophysical Investigations

4.10.1 General Geophysical investigations include surface geophysical surveys and borehole logging and other testing techniques, which are important for determining subsurface engineering properties and geologic and hydrologic characteristics, features, and conditions. Data from these investigations should be used to provide more continuous, and possibly deeper, subsurface information for filling in between data derived from surface outcrops, trenches, and boreholes and correlating data from other sources.

Available geophysical and borehole logging methods are listed in Appendix E to this guide and in EM-1110-1-1802, Geophysical Exploration for Engineering and Environmental Investigations, issued

1995 (Ref. 24). A geophysical exploration should consider the following factors:

(1) Subsurface and surface geophysical investigations cannot be substituted for each other. Both surface and subsurface geophysical investigations should be conducted to validate and calibrate site investigation results.

(2) For subsurface material engineering properties that could have high consequences if they are not determined properly, or are deemed critical to safe performance of the facility, multiple tests using different methods are recommended to capture uncertainties.

(3) Geophysical explorations should be carried out by personnel having the necessary technical background and experience in the techniques used.

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(4) Information related to acquisition of raw and processed field test data (e.g., spacing of data collection locations and instrument settings) should be recorded following applicable standards and quality assurance/quality control procedures to allow for proper interpretation of test results.

Selection of the appropriate penetration depths for geophysical investigations shall consider the need for information on site-specific stratigraphy and parameters of the materials encountered for input to analyses of site seismic response, soil-structure interaction, and foundation/structure stability. To properly determine site shear wave velocity profiles, borehole testing methods (e.g., P-S suspension logging and crosshole testing) combined with surface geophysical tests, such as seismic refraction and reflection surveys and spectral analysis of surface wave (SASW) methods (Ref. 25), should be used to cross-check and consolidate test results. Applicable ASTM and American Society of Civil Engineers standards should be used when conducting geophysical investigations.

4.10.2 Surface Geophysics Recommended surface geophysical techniques include seismic methods (e.g., reflection, refraction, and surface wave methods), electrical methods (e.g., resistivity), electromagnetic methods (e.g., ground-penetrating radar), and potential field methods (e.g., gravity and magnetics). Surface geophysical methods can be used to (1) measure shear-wave velocity profiles, (2) determine subsurface geologic conditions such as strata layers and thickness, faults, voids, and underground objects, and

(3) derive important material engineering properties (e.g., elastic moduli). The surface geophysical measurements should be correlated with borehole geophysical data and geologic logs to derive maximum benefit from the measurements.

4.10.3 Borehole Geophysics Geophysical borehole logs are very useful for determining geologic, hydrologic, and engineering properties of subsurface materials, including correlation of lithologic units between boreholes. A suitable suite of geophysical logging methods (Ref. 23) should be used for borehole geophysics study.

Appendix E to this guide lists some of the applicable geophysical logging methods, along with the geologic characteristics and engineering parameters the methods can help to determine.

Crosshole and single borehole geophysical methods can be used to obtain detailed information about subsurface materials in both horizontal and vertical directions. These methods can be used to determine site shear wave velocity profiles and derive engineering and hydrogeologic properties, such as shear modulus, porosity, and permeability. When very detailed information is needed, tomographic methods can be used to determine the geophysical properties of materials between boreholes.

Geophysical borehole logging methods include P-S suspension (Ref. 26), caliper, gamma, electrical resistivity, electromagnetic induction, fluid resistivity, temperature, flowmeter, television, acoustic televiewer, and other logs. These borehole loggings can measure in situ seismic waves;

determine lithology; measure dip and strike of important structural features of the rock units; evaluate intrusion of grout into the rock mass; distinguish and analyze fractures, shear zones, soft zones, cavities, and other discontinuities; and characterize water quality and flow.

Borehole logging and crosshole shear-wave measurements are generally low-strain measurements. In rock, these measurements provide a suitable approximation of shear modulus even under high-strain conditions. In soil, the shear modulus depends strongly on strain level. Therefore, these methods are usually insufficient because nonlinear effects can occur that may lead to misinterpretation of the test results. Laboratory tests (e.g., resonant column torsional shear test) are more promising for shear modulus determination.

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4.11 Logs of Subsurface Investigations It is important to have a complete and detailed log for every borehole. Boring logs should contain dates, locations, and depths of all borings, as well as elevations that are related to a permanent benchmark for the top and bottom of borings, boundaries of soil layers and rock units, and the level at which the water table was encountered. In addition, classification and description of soil layers and rock units, blow count values obtained from SPTs, percent recovery of rock core, quantity of core not recovered for each core interval or drill run, and rock quality designation should be noted. The factors that are needed for blow count correction, such as the type of sampler, hammer, and drill rod used in the SPT test, should also be recorded.

Results of field permeability tests and geophysical borehole logging should be included on the logs. The type of tools used to make the boring should be recorded. Notes should be provided for everything significant to the interpretation of subsurface conditions, such as drilling rate, settling or dropping of drill rods, abnormally low resistance to drilling or advance of samplers, core loss, and instability or heave of the side and bottom of boreholes. Influx of ground water, depths and amounts of water or drilling mud losses and depths at which circulation is recovered, and any other unique feature or occurrence should be recorded on the boring logs and geologic cross sections. Incomplete or abandoned borings should be described with the same care as successfully completed borings.

Logs of the walls and floor of exploratory trenches and other excavations should be presented in a graphic format that shows important components of the soil and structural features in rock units in sufficient detail to permit independent evaluation. Photomosaic panoramas can provide additional perspective and verification of trench features. Locations of all exploration efforts should be recorded in a GIS database and shown on geologic cross sections along with elevations and all pertinent data.

5. Ground Water Investigations Knowledge of ground water conditions and the relationship of those conditions to surface water and variations associated with seasons or tides is needed for foundation analyses. Ground water levels and conditions are normally observed in boreholes at the time they are drilled. However, these observations should be supplemented by additional data from properly installed wells with piezometers that are monitored at regular intervals from time of installation at least through the construction period.

Appendix G to this guide tabulates types of instruments for measuring ground water pressure and the advantages and limitations of each. ASTM D5092, Standard Practice for Design and Installation of Groundwater Monitoring Wells (Ref. 27) provides guidance on the design and installation of ground water monitoring wells. Types of piezometers, construction details, and sounding devices are described in EM 1110-2-1908, Instrumentation of Embankment Dams and Levees, issued 1995 (Ref. 28).

Ground water conditions should be observed during site investigations, and water level measurements should be taken in exploratory borings. Ground water or drilling mud level should be measured at the start of each workday for borings in progress, at the completion of drilling, and when water levels in the borings have stabilized. Ground water observation wells should be installed in as many locations as needed to adequately define the ground water environment. Pumping tests are preferred for evaluating local permeability and conductivity parameters and the level of confinement between aquifers.

These parameters are input into calculations for assessing dewatering requirements for construction and operation of the plant. For major excavations where construction dewatering is required, piezometers or observation wells should be used during construction to monitor the ground water surface and pore pressures beneath the excavation and in the adjacent ground. This guide does not cover ground water monitoring during construction of plants that are designed with permanent dewatering systems.

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In areas where perched ground water tables or artesian aquifer systems are expected, piezometers should be installed in each ground water element so that the piezometric level can be determined for the particular aquifer or ground water unit. Care should be taken in the design and installation of piezometers to prevent hydraulic communication between aquifers. The occurrence of artesian pressure in borings should be noted on boring logs, and the artesian heads should be measured and logged.

6. Construction Mapping It is necessary to confirm that in situ conditions revealed in excavations for safety-related structures were accurately captured and interpreted during the preconstruction site characterization stage to ensure that information related to actual in situ conditions is properly incorporated into plant design analyses. Detailed geologic mapping should be performed for all construction excavations for safety-related structures and other excavations important for verification of subsurface conditions (e.g., cut slopes, tunnels, chambers, and water inlets and outlets). Particular attention should be given to geologic features and characteristics that might be important in assessment of the behavior of foundation materials, including tectonic and nontectonic features and lithologic variations, which might be undetected and different from what was assumed based on the results of site investigations prior to excavations. The detailed geologic mapping should be performed after the completion of excavations and before placement of backfill.

The importance of the geologic mapping is reinforced by the geologic mapping license condition normally imposed in a combined or construction license. This license condition requires a licensee to commit to performing the following associated activities: (1) conduct detailed geologic mapping of excavations for safety-related structures, (2) examine and evaluate geologic features discovered in those excavations, and (3) notify the NRC once the excavations are open for inspection by NRC staff. Changes in foundation design that result from information acquired by the detailed geologic mapping should be noted on appropriate plans and included in maps, cross sections, and the database. All pertinent newly discovered geologic features should be evaluated for their potential impact on foundation materials. This evaluation might require relative or absolute age dates on certain features and particular tectonic structures such as faults and shear zones. The maps, cross sections, and database should include any features installed to improve, modify, or control geologic conditions (e.g., reinforcing systems, permanent dewatering systems, and special treatment areas). Photographic records of foundation geologic mapping and treatments should be made and retained in the database. The GIS and other databases should be continuously updated, up to and including the construction phase, resulting in inclusion of final as-built information in the database.

Appendix A to NUREG/CR-5738 provides detailed guidance on appropriate technical procedures for geologic mapping of foundation materials. Geologic mapping of tunnels and other underground openings must be planned differently from foundation mapping. Technical procedures for mapping tunnels are outlined in Appendix B to NUREG/CR-5738 and can be modified for large chambers. The individual in charge of foundation geologic mapping should be familiar with plant design and subsurface features and characteristics based on previous site investigations. This person should consult with plant design personnel during excavation whenever differences between the actual geology and the design-basis geologic model are discovered. The same individual should be involved in all decisions about changes in plant foundation design and any additional foundation treatments that might be necessary based on actual observed conditions of the foundation materials.

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7. Support Functions

7.1 Surveying, Mapping, and Development of the GIS Database Surveying is an important function that should accompany all essential site investigation activities from reconnaissance through construction mapping. Many methods of surveying are available, from traditional triangulation or plane table work and leveling to electronic distance and GPS measurements.

For mapping small areas, plane table methods may still be rapid enough. In most cases, however, GPS or differential GPS together with automated recording and computing procedures is the most suitable method. Procedures for GPS surveying can be found in EM-1110-1-1003, NAVSTAR Global Positioning System Surveying, issued 2011 (Ref. 18). The GPS measurements and other surveyed locations should be tied to National Geodetic Survey (NGS) markers to be compatible with topographic and digital maps of various types. Survey results should have adequate precision with no more than

0.3 meter (1.0 foot) onshore and 1.5 meters (5.0 feet) offshore for plan coordinates and 3 centimeters

(0.1 foot) onshore and 0.3 meter (1.0 foot) offshore for elevation. For greater accuracy, it might still be necessary to perform a certain amount of conventional leveling.

A suitable coordinate system for the site should be chosen. Three-dimensional coordinate systems include the World Geodetic System of 1984, the International Terrestrial Reference Frame, and the North American Datum of 1983 (NAD 83). Coordinates should be referred to NAD 83 to be legally recognized in most U.S. jurisdictions. Moreover, NGS provides software for converting the ellipsoid-based heights of NAD 83 to the sea-level-based heights that appear on topographic maps. NAD 83 coordinates are readily determined when measurements tie the site to an NGS marker.

All three-dimensional information should be entered into a GIS database because data of various types, in the form of tables, can be associated with a coordinate system and recalled to form the desired graphical output. Choice of a specific system is up to the applicant, but the data should be in a format that is readily readable. It is necessary to have personnel with experience in surveying and storing and displaying data in a GIS database throughout all phases of site investigation and construction in order to

(1) accurately record information obtained, (2) place geologic, geotechnical, sampling, and testing information into a spatial context, and (3) permit visual display of data on maps and cross sections.

Development of the GIS database is an essential activity that should be given proper emphasis and support by applicants and licensees.

7.2 Records, Sample Retention, and Quality Assurance All data acquired during site characterization investigations should be organized into logical categories and preserved as a permanent record, at least until the power plant is licensed to operate and all matters relating to the interpretation of subsurface conditions at the site have been resolved. Much of the data will already be part of the GIS database, but other data and records, such as logs of operations, photographs, test results, and engineering evaluations and calculations, should also be preserved for further reference.

Samples and rock cores from principal borings should also be retained. Regulatory Position 4.3.3 and Chapter 7 of NUREG/CR-5738 describe procedures for handling and storing samples. The need to retain samples and cores beyond the recommended time is a matter of judgment and should be evaluated on a case-by-case basis. For example, soil samples in tubes will deteriorate with time and will not be suitable for undisturbed testing. However, they may be used as a visual record of the foundation material.

Similarly, rock cores subject to slaking and rapid weathering, such as shale, will also deteriorate.

Photographs of soil samples and rock cores, with field and final logs of all borings, should be preserved for a permanent record.

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The site investigations should be included in the overall quality assurance program for plant design and construction according to the guidance in RG 1.28, Quality Assurance Program Criteria (Design and Construction) (Ref. 29), and the requirements of Appendix B, Quality Assurance Criteria for Nuclear Power Plants and Fuel Reprocessing Plants, to 10 CFR Part 50. Therefore, field operations and records preservation should be conducted in accordance with quality assurance principles and procedures.

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D. IMPLEMENTATION

The NRC staff may use this regulatory guide as a reference in its regulatory processes, such as licensing, inspection, or enforcement. However, the NRC staff does not intend to use the guidance in this regulatory guide to support NRC staff actions in a manner that would constitute backfitting as that term is defined in 10 CFR 50.109, Backfitting, and as described in NRC Management Directive 8.4, Management of Backfitting, Forward Fitting, Issue Finality, and

=

Information Requests

=

, (Ref. 30), nor does the NRC staff intend to use the guidance to affect the issue finality of an approval under

10 CFR Part 52, Licenses, Certifications, and Approvals for Nuclear Power Plants. The staff also does not intend to use the guidance to support NRC staff actions in a manner that constitutes forward fitting as that term is defined and described in Management Directive 8.4. If a licensee believes that the NRC is using this regulatory guide in a manner inconsistent with the discussion in this Implementation section, then the licensee may file a backfitting or forward fitting appeal with the NRC in accordance with the process in Management Directive 8.4.

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REFERENCES1

1. U.S. Code of Federal Regulations, Domestic Licensing of Production and Utilization Facilities, Part 50, Chapter I, Title 10, Energy.

2. U.S. Code of Federal Regulations, Licenses, Certifications, and Approvals for Nuclear Power Plants, Part 52, Chapter I, Title 10, Energy.

3. U.S. Code of Federal Regulations, Reactor Site Criteria, Part 100, Chapter I, Title 10,

Energy.

4. U.S. Nuclear Regulatory Commission, Standard Review Plan for the Review of Safety Analysis Reports for Nuclear Power Plants: LWR Edition, NUREG-0800.

5. U.S. Nuclear Regulatory Commission, Seismic Design Classification for Nuclear Power Plants, Regulatory Guide 1.29, Revision 5, July 2016.

6. U.S. Nuclear Regulatory Commission, Standard Format and Content of Safety Analysis Reports for Nuclear Power Plants: LWR Edition, Regulatory Guide 1.70, Revision 3, November 1978.

7. U.S. Nuclear Regulatory Commission, Applications for Nuclear Power Plants (LWR Edition),

Regulatory Guide 1.206, Revision 1, October 2018.

8. U.S. Nuclear Regulatory Commission, Laboratory Investigations of Soils and Rocks for Engineering Analysis and Design of Nuclear Power Plants, Regulatory Guide 1.138, Revision 3, December 2014.

9. U.S. Nuclear Regulatory Commission, Guidelines for Categorizing Structures, Systems, and Components in Nuclear Power Plants According to Their Safety Significance, Regulatory Guide 1.201, Revision 1, May 2006.

10. U.S. Nuclear Regulatory Commission, General Site Suitability Criteria for Nuclear Power Stations, Regulatory Guide 4.7, Revision 3, March 2014.

11. U.S. Nuclear Regulatory Commission, A Performance-Based Approach to Define the Site-Specific Earthquake Ground Motion, Regulatory Guide 1.208, March 2007.

12. National Research Council, Geotechnical Site Investigations for Underground Projects, Vols. 1-2, The National Academies Press, Washington, DC, 1984.

13. U.S. Nuclear Regulatory Commission, Nuclear Regulatory Commission International Policy Statement, Federal Register, Vol. 79, No. 132, July 10, 2014, pp. 39415-3941.

1 Publicly available NRC published documents are available electronically through the NRC Library on the NRCs public Web site at http://www.nrc.gov/reading-rm/doc-collections/ and through the NRCs Agencywide Documents Access and Management System (ADAMS) at http://www.nrc.gov/reading-rm/adams.html. The documents can also be viewed online or printed for a fee in the NRCs Public Document Room (PDR) at 11555 Rockville Pike, Rockville, MD. For problems with ADAMS, contact the PDR staff at (301) 415-4737 or (800) 397-4209; fax (301) 415-3548; or e-mail pdr.resource@nrc.gov.

RG 1.132, Page 26

14. U.S. Nuclear Regulatory Commission, Regulatory Guides, Management Directive 6.6, May 2, 2016, ADAMS Accession No. ML18073A170.

15. International Atomic Energy Agency, Geotechnical Aspects of Site Evaluation and Foundations for Nuclear Power Plants, IAEA Safety Standards Series No. NS-G-3.6, 2005.2

16. International Atomic Energy Agency, Seismic Hazards in Site Evaluation for Nuclear Installations. IAEA Specific Safety Guide No. SSG-9, 2010.

17. Environmental Laboratory, Corps of Engineers Wetlands Delineation Manual, Technical Report Y-87-1, U.S. Army Corps of Engineers Waterways Experiment Station, Vicksburg, MS,

1987.

18. U.S. Army Corps of Engineers, NAVSTAR Global Positioning System Surveying, Engineer Manual (EM) 1110-1-1003, Washington, DC, 2011.

19. U.S. Army Corps of Engineers, Geotechnical Investigations, Engineer Manual EM 1110-1-1804, Washington, DC, 2001.

20. Nicholson, G.A., In Situ and Laboratory Shear Devices for Rock: A Comparison, Technical Report GL-83-14, U.S. Army Corps of Engineers, Waterways Experiment Station, Vicksburg, MS, 1983.

21. Bowles, J.E., Foundation Analysis and Design, 5th Ed., McGraw-Hill, New York, 1996.

22. U.S. Army Corps of Engineers, Suggested Method for In Situ Determination of Direct Shear Strength (ISRM), RTH 321-80, Waterways Experiment Station, Vicksburg, MS, 1980.

23. ASTM International, Standard Guide for Planning and Conducting Borehole Geophysical Logging, ASTM D5753-05, 2010.3

24. U.S. Army Corps of Engineers, Geophysical Exploration for Engineering and Environmental Investigations, Engineer Manual EM 1110-1-1802, Washington, DC, 1995.

25. Gucunski, N., and R.D. Woods, Instrumentation for SASW Testing, Recent Advances in Instrumentation, Data Acquisition, and Testing in Soil Dynamics Proceedings, Geotechnical Special Publication No. 29, pp. 1-16, American Society of Civil Engineers, New York, 1991.

26. Diehl, J.G., Martin, A.J., and R.A. Steller, Twenty-Year Retrospective on the OYO P-S

Suspension Logger, Proceedings of the 8th U.S. National Conference on Earthquake Engineering, April 18-22, 2006, San Francisco, California.

2 Copies of International Atomic Energy Agency (IAEA) documents may be obtained through their Web site:

WWW.IAEA.Org/ or by writing the International Atomic Energy Agency, P.O. Box 100 Wagramer Strasse 5, A-1400

Vienna, Austria.

3 Copies of ASTM International (ASTM) standards may be purchased from ASTM, 100 Barr Harbor Drive, P.O.

Box C700, West Conshohocken, Pennsylvania 19428-2959; telephone (610) 832-9585. Purchase information is available through the ASTM Web site at http://www.astm.org.

RG 1.132, Page 27

27. ASTM International, Standard Practice for Design and Installation of Groundwater Monitoring Wells, ASTM D5092-04, 2010.

28. U.S. Army Corps of Engineers, Instrumentation of Embankment Dams and Levees, Engineer Manual EM 1110-2-1908 (Part 1), Washington, DC, 1995.

29. U.S. Nuclear Regulatory Commission, Quality Assurance Program Criteria (Design and Construction), Regulatory Guide 1.28, Revision 5, October 2017.

30. U.S Nuclear Regulatory Commission, Management of Backfitting, Forward Fitting, Issue Finality, and

=

Information Requests

=

, Management Directive 8.4, Washington, DC.

RG 1.132, Page 28

APPENDIX A

SPECIAL GEOLOGIC FEATURES AND CONDITIONS CONSIDERED IN OFFICE STUDIES

AND FIELD OBSERVATIONS (adapted from EM 1110-1-1804, U.S. ARMY CORPS OF ENGINEERS,

2001)

GEOLOGIC

FEATURE OR

CONDITION INFLUENCE ON PROJECT OFFICE STUDIES FIELD OBSERVATIONS QUESTIONS TO ANSWER

Landslides Stability of natural and excavated Presence or age in project area or at Estimate areal extent (length and width) and Are landslides found off site in slopes construction site should be determined. height of slope. geologic formations of the same type that will be affected by project construction?

Compute shear strength at failure. Do Estimate ground slope before and after slide What are probable previous and failure strengths decrease with age of (may correspond to residual angle of friction). present ground water levels?

slopes, especially for clays and clay shales?

Check highway and railway cuts and deep Do trees slope in an unnatural excavations, quarries, and steep slopes. direction?

Faults and faulting; Of decisive importance in seismic Determine existence of known faults and Verify presence of fault at site, if possible, Are lineaments or possible fault past seismic activity evaluations; age of the most recent fault history from available information. from surface evidence. Examine and consider traces apparent from regional fault movement may determine seismic Check potential fault traces identified on characteristics of geologically young alluvial aerial imagery?

design earthquake magnitude and may remote sensing imagery, Google Earth, deposits and river terraces in the site vicinity.

be indicative of high state of stress that and light detection and ranging (LiDAR).

could result in foundation heave or Compare geologic and seismicity maps.

overstress in underground works.

Examine existing boring logs for evidence Make field check of geologic maps, of faulting from offset of strata and structures, cellars, chimneys, roads, fences, indications of breccia and shear zones. pipelines, known faults, caves, inclination of trees, and offset in fence lines.

Joints and fractures High concentration of joints indicates Study satellite images, aerial photos, and Investigate orientation and density of joints. Are the joint sets related to weakness of bedrock and high strain. LiDAR and define all available lineaments Assess any cross-cutting relationships denudation and unloading or are and their relationship, if possible. between joint sets and estimate age of they tectonically formed? What is jointing. the current orientation of stress in the crust?

RG 1.132, Appendix A, Page A-1

APPENDIX A, Contd.

GEOLOGIC

FEATURE OR

CONDITION INFLUENCE ON PROJECT OFFICE STUDIES FIELD OBSERVATIONS QUESTIONS TO ANSWER

Stress relief Valley walls may have cracking Review pertinent geologic literature and Examine wells and piezometers in valleys to cracking and valley parallel to valley. Valley floors may reports for the valley area. Check existing determine if levels are lower than normal rebounding have horizontal cracking. In some clay piezometer data for abnormally low levels ground water regime (indicates valley shales, stress relief from valley erosion in valley sides and foundation; compare rebound not complete).

or glacial action may not be complete. with normal ground water levels outside valley.

Sinkholes; karst Might affect stability of foundation. Consider the local geology and Locate depressions in the field and measure Are potentially soluble rock units topography Major effect on location of structures stratigraphy from previous publications in size depth and slopes. Differences in present, such as limestone, and feasibility of potential site. site vicinity. Examine topographic maps elevation between center and edges may be dolomite, gypsum, anhydrite, or (old and recent), LiDAR, and aerial photos almost negligible or many feet. From local halite?

(old and recent) for evidence of undrained residents, attempt to date appearance of depressions and disappearing streams. sinkhole.

Consider the location and density of caves Are undrained depressions present in the vicinity. Consider alternate rock that cannot be explained by dissolution processes such as epigenic and Consider the presence, size, and frequency of voids identified in core. glaciation?

hypogenic systems.

Conduct field review of features identified in office studies. How do the water table and deeper aquifers inform understanding about cavern formation?

Is surface topography rough and irregular without apparent cause?

Anhydrites or Anhydrites in foundations beneath Determine possible existence from Look for surface evidence of uplift; seek local Are uplifts caused by possible gypsum layers major structures may hydrate and cause available geologic information and information on existing structures. anhydrite expansion or expansion, upward thrust, and delineate possible outcrop locations. explosion?

buckling.

Gypsum may cause settlement, Check area carefully for caves or other subsidence, collapse, or piping. evidence of solution features.

Solution during life of structure may be damaging.

RG 1.132, Appendix A, Page A-2

APPENDIX A, Contd.

GEOLOGIC

FEATURE OR

CONDITION INFLUENCE ON PROJECT OFFICE STUDIES FIELD OBSERVATIONS QUESTIONS TO ANSWER

Caves Extent may affect project feasibility or See studies suggested for karst. Observe cave walls carefully for evidence of Are any stalactites or stalagmites cost. Can provide evidence about faults and recent faulting. Estimate age of any broken from apparent ground faulting that may relate to seismic broken stalactites or stalagmites from column displacement or shaking?

design. Can result from unrecorded rings.

mining activity in the area.

Erosion resistance Determines need for total or partial Locate contacts of potentially erosive Note stability of channels and degree of Are channels stable or have they channel slope protection. strata along drainage channels. erosion and stability of banks. shifted frequently? Are banks stable or easily eroded? Is there extensive bank sliding?

Internal erosion Affects stability of foundations and Locate possible outcrop areas of sorted Examine seepage outcrop areas of slopes and dam abutments. Gravelly sands or alluvial materials or terrace deposits. riverbanks for piping.

sands with deficiency of intermediate particle sizes may be unstable and develop piping when subject to seepage flow.

Area subsidence Area subsidence endangers long-term Locate areas of high ground water Check project area for new wells or new Are there any plans for new or stability and performance of project. withdrawal, oil and gas fields, and mining activity. increased recovery of subsurface subsurface mineral extraction (coal, water or mineral resources?

solution mining, etc.) areas.

Collapsing soils Determines need for removal of Determine how deposits were formed Examine surface deposits for voids along Were materials deposited by mud shallow foundation materials that during geologic time and any collapse eroded channels, especially in steep valleys flows?

would collapse upon wetting problems in area. eroded in fine-grained sedimentary formations.

RG 1.132, Appendix A, Page A-3

APPENDIX A, Contd.

GEOLOGIC

FEATURE OR

CONDITION INFLUENCE ON PROJECT OFFICE STUDIES FIELD OBSERVATIONS QUESTIONS TO ANSWER

Locally lowered May cause minor to large local and Determine if heavy pumping from wells Obtain ground water levels in wells from ground water area settlements and result in flooding has occurred in project area; contact city owners and information on withdrawal rates near rivers or open water and and State agencies and U.S. Geological and any planned increases. Observe condition differential settlement of structures. Survey. of structures. Contact local water plant operators.

Abnormally low May indicate effective stresses are still Compare normal ground water levels with Is a possible cause from past pore water increasing and may cause future slope piezometric levels if data are available. reduction in vertical stresses pressures (lower instability in valley sites. (e.g., deep glacial valley or canal than anticipated excavations such as the Panama from ground water Canal in clay shales where pore levels) water pressures were reduced by stress relief)?

In situ shear Provides early indication of stability of Locate potential slide areas. Existing slope Estimate slope angles and heights, especially Are existing slopes consistently strength from excavated slopes or abutment, and failures should be analyzed to determine at river bends where undercutting erosion flat, indicating residual strengths natural slopes natural slopes around reservoir area. minimum in situ shear strengths. occurs. Determine if flat slopes are associated have been developed?

with mature slide or slump topography or with erosion features.

Swelling soils and Highly preconsolidated clays and clay Determine potential problem and location Examine roadways founded on geologic Do seasonal ground water and shales shales may swell greatly in excavations of possible preconsolidated strata from formations similar to those at site. Check rainfall or watering of shrubs or or upon increase in moisture content. available information. condition of buildings and effects of rainfall trees cause heave or settlement?

and watering.

Varved clays Pervious layers may cause more rapid Determine areas of possible varved clay Check natural slopes and cuts for varved settlement than anticipated. May appear deposits associated with prehistoric lakes. clays; check settlement behavior of structures.

to be unstable because of uncontrolled Determine settlement behavior of seepage flow through pervious layers structures in the area.

between overconsolidated clay layers or may have weak clay layers. May be unstable in excavations unless well points are used to control ground water.

RG 1.132, Appendix A, Page A-4

APPENDIX A, Contd.

GEOLOGIC

FEATURE OR

CONDITION INFLUENCE ON PROJECT OFFICE STUDIES FIELD OBSERVATIONS QUESTIONS TO ANSWER

Dispersive clays Is a major factor in selecting soils for Check with Soil Conservation Service and Look for peculiar erosional features, such as embankment dams and levees. other agencies regarding behavior of vertical or horizontal cavities in slopes or existing small dams. unusual erosion in cut slopes. Perform crumb test.

Riverbank and other Has a major effect on riverbank Locate potential areas of loose Check riverbanks for scallop-shaped failure liquefaction areas stability and on foundation stability in fine-grained alluvial or terrace sand, most with narrow neck (may be visible during low seismic areas. likely along riverbanks where loose sands water). If present, determine shape, depth, are present and erosion is occurring. average slope, and slope of adjacent sections.

Liquefaction in wooded areas may leave trees inclined at erratic angles. Look for evidence of sand boils in seismic areas.

Filled areas Relatively recent filled areas would Check old topo maps, if available, for Obtain local history of site from cause large settlements. Such fill areas depressions or gullies not shown on more area residents.

may be overgrown and not detected recent topo maps.

from surface or even subsurface evidence.

Local Local areas of a site may have been Obtain local history from residents overconsolidation overconsolidated from past heavy of area.

from previous site loadings of lumber or material storage usage piles.

RG 1.132, Appendix A, Page A-5

APPENDIX B

SOURCES OF GEOLOGIC INFORMATION (adapted from EM 1110-1-1804, U.S. ARMY CORPS OF

ENGINEERS, 2001)

TYPE OF

AGENCY INFORMATION DESCRIPTION REMARKS

U.S. Geological Topographic U.S. 7.5-minute series 1:24,000 (supersedes 1:31,680); Puerto Rico 7.5-minute Orthophotoquad monocolor and color infrared maps also Survey (USGS) maps series 1:20,000 (supersedes 1:30,000); Virgin Island 1:24,000 series. produced in 7.5-minute and 15-minute series. New index of maps for each State started in 1976. Status of current mapping U.S. 15-minute series 1:62,500 (1:63,360 for Alaska) from USGS regional offices and in monthly USGS bulletin, New Publications of the U.S. Geological Survey.

U.S. 1:100,000-scale series (quadrangle, county, or regional format) Topographic and geological information from the USGS can be accessed through the Earth Science Information Center (ESIC)

U.S. 1:50,000-scale county map series (1-800-USAMAPS).

U.S. 1:250,000-scale series Digital elevation models are available for entire U.S. at 1:250,000, and for certain areas at 1:100,000 and 1:24,000 scales Digital line graphs are available for some areas at 1:24,000 and 1:65,000,

1:100,000 for

• hydrography

• transportation

• U.S. Publication Survey

• boundaries

• hypsography USGS Geology maps 1:24,000 (1:20,000 Puerto Rico), 1:62,500, 1:100,00, and 1:250,000 quadrangle New index of geologic maps for each State started in 1976. List and reports series includes surficial bedrock and standard (surface and bedrock) maps with of geologic maps and reports for each State published major landslide areas shown on later editions 1:500,000 and 1:2,500,000 periodically.

USGS Miscellaneous Landslide susceptibility rating, swelling soils, engineering geology, water Miscellaneous Investigation Series and Miscellaneous Field maps and reports resources, and ground water. Studies Series, maps and reports, not well cataloged; many included as open file reports.

USGS Special maps 1:7,500,000 and 1:1,000,000: Limestone Resources, Solution Mining Subsidence, Quaternary Dating Applications, Lithologic Map of U.S., Quaternary Geologic Maps.

RG 1.132, Appendix B, Page B-1

APPENDIX B, Contd.

TYPE OF

AGENCY INFORMATION DESCRIPTION REMARKS

USGS Hydrologic maps Hydrologic Investigations Atlases with a principal map scale of 1:24,000; includes Some maps show ground water contours and location of wells.

water availability, flood areas, surface drainage precipitation and climate, geology, availability of ground and surface water, water quality and use, and streamflow characteristics USGS Earthquake Seismic maps of each State (started in 1978 with Maine); field studies of fault Operates National Strong-Motion Network. National hazard zones; relocation of epicenters in eastern United States; hazards in the Mississippi Earthquake Information Service publishes monthly listing of Valley area; analyses of strong motion data; state-of-the-art workshops epicenters worldwide. Information is available through ESIC

(1-800-USAMAPS).

USGS Mineral resources Bedrock and surface geologic mapping; engineering geologic investigations; map of U.S. power-generating plants (location of built, under construction, planned, and type); 7.5-minute quadrangle geologic maps and reports on surface effects of subsidence into underground mine openings of eastern Powder River Basin, Wyoming USGS Bibliography Bibliography of North American Geology (USGS 1973) USGS professional paper American Geological Bibliography American Geological Institute print counterpart.

Institute Bibliography and Index of Geology to Geo Ref digital index (USGS 1969 to present, 12 monthly issues plus yearly cumulative index Geological Society of America 1973)

Decade of North American Geology series National Oceanic and Earthquake National Geophysical Data Center in Colorado has extensive earthquake hazard Atmospheric hazards information (303-497-6419)

Administration (NOAA)

National Aeronautics Remote sensing Landsat, Skylab imagery and Space data Administration (NASA)

NOAA Remote sensing data Space Imaging Earth Remote sensing Multiband satellite imagery with meter resolution Observation Satellite data (EOSAT)

RG 1.132, Appendix B, Page B-2

APPENDIX B, Contd.

TYPE OF

AGENCY INFORMATION DESCRIPTION REMARKS

U.S. Fish and Wildlife Wetlands The National Wetlands Inventory maps at 1:24,000 for most of the contiguous Available as maps or mylar overlays Service United States USGS Flood-prone area 1:24,000 series maps outlining floodplain areas not included in Corps of Engineers Stage 2 of 1966 89th Congress House Document 465 maps reports or protected by levees U.S. Army Engineer Earthquake State-of-the-Art for Assessing Earthquake Hazards in the United States, Series of 19 reports, 1973 to present Waterways hazard Miscellaneous Paper S-73-1 Experiment Station (USAEWES)

International Union of Worldwide Commission for the Geological Map of the World publishes periodic reports on Geological Sciences mapping worldwide mapping in Geological Newsletter Natural Resources Soil survey 1:15,840 or 1:20,000 maps of soil information on photomosaic background for Reports since 1957 contain engineering uses of soils mapped, Conservation Service reports each country. Recent reports include engineering test data for soils mapped, depth parent materials, geologic origin, climate, physiographic to water and bedrock, soil profiles grain-size distribution, engineering setting, and profiles.

interpretation, and special features. Recent aerial photo coverage of many areas.

Soils maps at 1:7,500,000, 1:250,000, and 1:12,000 scale are available in digital format for some areas.

Federal Emergency Earthquake National Earthquake Hazards Reduction Program, Recommended Provisions for Management Agency hazard Seismic Regulations for New Buildings and Older Structures, issued 1997, includes seismic maps.

State Geologic Geologic maps State and county geologic maps; mineral resource maps; special maps such as for List of maps and reports published annually, unpublished Agencies and reports swelling soils; bulletins and monographs; well logs; water resources, ground water information by direct coordination with State geologist studies Defense Mapping Topographic Standard scales of 1:12,500, 1:50,000, 1:250,000, and 1:1,000,000 foreign and Index of available maps from DMA

Agency (DMA) maps worldwide coverage, including photomaps American Association Geological Scale approximately 1 inch to 30 miles shows surface geology and includes Published as 12 regional maps, including Alaska and Hawaii of Petroleum highway map generalized time and rock unit columns, physiographic map, tectonic map, Geologists series geologic history summary, and sections Tennessee Valley Topographic Standard 7.5-minute TVA-USGS topographic maps, project pool maps, Coordinate with TVA for available specific information.

Authority (TVA) maps, geologic large-scale topographic maps of reservoirs, geologic maps and reports in maps and reports connection with construction projects U.S. Department of Geologic maps Maps and reports prepared during project planning and design studies Reports on completed projects can be obtained by interlibrary Interior, Bureau of and reports loan or from USAEWES.

Reclamation RG 1.132, Appendix B, Page B-3

APPENDIX B, Contd.

TYPE OF

AGENCY INFORMATION DESCRIPTION REMARKS

Agricultural Aerial The APFO offers aerial photographs across the United States, typically a series of Information is available at 801-975-3503.

Stabilization and photographs photographs taken at different times, as available for a given site.

Conservation Services Aerial Photography Field Office (APFO)

USGS Earth Aerial The EDC houses the nations largest collection of space- and aircraft-acquired Information is available at 605-594-6151 or 1-800-USAMAPS.

Resources Observation photographic imagery.

Systems (EROS) coverage Center (EDC)

Satellite Pour Remote sensing High-resolution multispectral imagery produced by Frances SPOT satellite The contact number for SPOT images is 800-275-7768.

lObservation de la imagery imager is available for purchase.

Terre (SPOT)

Google Earth Combination of Maps the Earth by the superimposition of images obtained from satellite imagery, Available online.

satellite imagery, aerial photography, and geographic information system (GIS) onto a three- aerial dimensional globe. Resolution varies from 15 meters to 15 centimeters.

photography, and geographic information RG 1.132, Appendix B, Page B-4

APPENDIX C

METHODS OF SUBSURFACE EXPLORATION

METHOD PROCEDURE APPLICABILITY LIMITATIONS

1. Methods of Access for Sampling, Test, or Observation Pits, trenches, Excavation is made by hand, large auger, or Visual observation, photography, disturbed and Depth of unprotected excavations is limited by ground water or shafts, tunnels digging machinery. undisturbed sampling, in situ testing of soil and rock. safety considerations. May need dewatering.

Auger boring Boring is advanced by hand auger or power Recovery of remolded samples and determining Will not penetrate bounders or most rock.

auger. ground water levels. Access for undisturbed sampling of cohesive soils.

Hollow-stem auger Boring is advanced by means of Access to undisturbed or representative sampling Should not be used with coarse-grained soils. Not suitable for boring continuous-flight helix auger with through hollow stem with thin-wall tube sampler, core undisturbed sampling in loose sand or silt. Not recommended below hollow-center stem. barrel, or split-barrel sampler. the ground water table in cohesionless soils.

Wash boring Boring is advanced by chopping with light Cleaning out and advancing hole in soil between Suitable for use with sampling operations in soil only if done with bit and by jetting with upward deflected jet. sample intervals. low water velocities and with upward deflected jet.

Rotary drilling Boring is advanced by rotating drilling bit; Boring in soil or rock. Drilling mud should be used in coarse-grained soils. Bottom cuttings removed by circulating drilling discharge bits are not suitable for use with undisturbed sampling in fluid. soil unless combined with protruding core barrel, as in Denison sampler, or with upward deflected jets.

Percussion drilling Boring is advanced by air-operated impact Detection of voids and zones of weakness in rock by Not suitable for use in soils.

hammer. changes in drill rate or resistance. Access for in situ testing or logging.

Sonic drilling Boring is advanced by vibrating entire drill Drilling for coarse alluvial deposit that consists of While sonic drill usually can produce continuous samples and with string that strongly reduces friction on the significant amount of gravel and cobble. good recovery, the samples retrieved from the plastic sampling drill string and drill bit due to liquefaction, tubes are highly disturbed and broken up.

inertia effects, and a temporary reduction of porosity of the soil.

Cable drilling Boring is advanced by repeated dropping of Advancing hole in soil or rock. Access for sampling, Causes severe disturbance in soils; not suitable for use with heavy big; removal of cuttings by bailing in situ testing, or logging in rock. Penetration of hard undisturbed sampling methods.

layers, gravel, or boulders in auger borings.

Continuous Boring is advanced by repeated pushing of Recovery of representative samples of cohesive soils Effects of advance and withdrawal of sampler result in disturbed sampling or sampler, or closed sampler is pushed to and undisturbed samples in some cohesive soils. sections at top and bottom of sample. In some soils, entire sample displacement boring desired depth and sample is taken. may be disturbed. Best suited for use in cohesive soils. Continuous sampling in cohesionless soils may be made by successive reaming and clearing of hole between sampling.

RG 1.132, Appendix C, Page C-1

APPENDIX C, Contd.

METHOD PROCEDURE APPLICABILITY LIMITATIONS

2. Methods of Sampling Soil or Rock Hand cut or Sample is cut by hand from soil exposed in Highest quality samples in all soils and in soft rock. Requires accessible excavation and dewatering if below water cylindrical sample excavation. table. Extreme care is required in sampling cohesionless soils.

Fixed-piston Thin-walled tube is pushed into soil with Undisturbed samples in cohesive soils, silts, and sands Some types do not have a positive means to prevent piston sampler fixed piston in contact with top of sample above or below the water table. movement.

during push.

Hydraulic piston Thin-walled tube is pushed into soil by Undisturbed samples in cohesive soils, silts, and sands Not possible to determine amount of sampler penetration during sampler (Osterberg hydraulic pressure. Fixed piston is in contact above or below the water table. push. Does not have vacuum breaker in piston.

Sampler) with top of sample during push.

Free-piston sampler Thin-walled tube is pushed into soil. Piston Undisturbed samples in stiff, cohesive soils. May not be suitable for sampling in cohesionless soils. Free piston rests on top of soil sample during push. Representative samples in soft to medium cohesive provides no control of specific recovery ratio.

soils and silts.

Open drive sampler Thin-walled open tube is pushed into soil. Undisturbed samples in stiff, cohesive soils. Small diameter of tubes may not be suitable for sampling in Representative samples in soft to medium cohesive cohesionless soils or for undisturbed sampling in uncased soils and silts. boreholes. No control of specific recovery ratio.

Swedish Foil Sample tube is pushed into soil, while Continuous undisturbed samples up to 20 meters Small sampler diameter increases sample disturbance. Not suitable Sampler stainless steel strips unrolling from spools (66 feet) long in very soft to soft clays. for soils containing gravels, sand layers, or shells, which may envelop sample. Piston, fixed by chain from rupture foils and damage samples. Difficulty may be encountered in surface, maintains contact with top of alternating hard and soft layers, with squeezing of soft layers and sample. reduction in thickness. Requires experienced operator.

Pitcher sampler Thin-walled tube is pushed into soil by Undisturbed samples in stiff, hard, brittle, cohesive Frequently ineffective in cohesionless soils.

spring above sampler, while outer core bit soils and sands with cementation, and in soft rock.

reams hole. Cuttings are removed by Effective in sampling alternating hard and soft layers.

circulating drilling fluid. Representative samples in soft-to-medium cohesive soils and silts. Disturbed samples may be obtained in cohesionless materials with variable success.

Split-barrel or Split-barrel tube is driven into soil by blows Representative samples in soils other than Samples are disturbed and not suitable for tests of physical split-spoon sampler of falling ram. Sampling is carried out in coarse-grained soils. properties.

conjunction with Standard Penetration Test.

Auger sampling Auger drill used to advance hole is Determine boundaries of soil layers and obtain samples Samples are not suitable for physical property or density tests.

withdrawn at intervals for recovery of soil of soil classification. Large errors in locating strata boundaries may occur without close samples from auger flights. attention to details of procedure. In some soils, particle breakdown by auger or sorting effects may result in errors in determining gradation.

RG 1.132, Appendix C, Page C-2

APPENDIX C, Contd.

METHOD PROCEDURE APPLICABILITY LIMITATIONS

Rotary core barrel Hole is advanced by core bit while core Core samples in competent rock and hard soils with Because recovery is poorest in zones of weakness, samples sample is retained within core barrel or single tube core barrel. Core samples in poor or broken generally fail to yield positive information on soft seams, joints, or within stationary inner tube. Cuttings rock may be obtainable with double tube core barrel other defects in rocks.

removed by drilling fluid. with bottom discharge bit.

Denison sampler Hole is advanced and reamed by core drill Undisturbed samples in stiff-to-hard cohesive soil, Not suitable for undisturbed sampling in loose, cohesionless soils while sample is retained in nonrotating inner sand with cementation, and soft rocks. Disturbed or soft, cohesive soils. Difficulties may be experienced in sampling core barrel with core catcher. Cuttings sample may be obtained in cohesionless materials with alternating hard and soft layers.

removed by circulating drilling fluid. variable success.

Shot core boring Boring is advanced by rotating single core Large-diameter cores and accessible boreholes in rock. Cannot be used in drilling at large angles to the vertical. Often (Calyx) barrel, which cuts by grinding with chilled ineffective in securing small diameter cores.

steel shot fed with circulating wash water.

Used shot and coarser cuttings are deposited in an annular cup, or calyx, above the core barrel.

Oriented integral Reinforcing rod is grouted into small Core samples in rock with preservation of joints and Samples are not well suited to tests of physical properties.

sampling diameter hole, then overcored to obtain an other zones of weakness.

annular core sample.

Wash sampling or Cuttings are recovered from wash water or Samples useful in conjunction with other data for Sample quality is not adequate for site investigations for nuclear cuttings sampling drilling fluid. identification of major strata. facilities.

Submersible Core tube is driven into soil by vibrator. Continuous representative samples in unconsolidated Because of high area ratio and effects of vibration, samples may be vibratory marine sediments. disturbed.

(Vibracore) sampler Underwater piston Core tube attached to drop weight is driven Representative samples in unconsolidated marine Samples may be seriously disturbed. Cable-supported piston corer into soil by gravity after a free fall of sediments. remains in contact with soil surface during drive.

controlled height.

Gravity corer Open core tube attached to drop weight is Representative samples at shallow depth in No control of specific recovery ratio. Samples are disturbed.

driven into soil by gravity after free fall. unconsolidated marine sediments.

RG 1.132, Appendix C, Page C-3

APPENDIX C, Contd.

METHOD PROCEDURE APPLICABILITY LIMITATIONS

3. Methods of In Situ Testing of Soil and Rock Standard Split-barrel sampler is driven into soil by Blow count may be used as an index of consistency or Extremely unreliable in silts, silty sands, or soils containing gravel.

Penetration Test blows of free-falling weight. Blow count for density of soil. May be used for detection of changes In sands below water table, positive head must be maintained in (SPT) each 15 centimeters (6 inches) of penetration in consistency or density in clays or sands. May be borehole. Determination of relative density in sands requires is recorded. used with empirical relationships to estimate relative site-specific correlation or highly conservative use of published density of clean sand. correlations. Results are sensitive to details of apparatus and procedure. The technique should not be applied to soils containing large amounts of cobbles.

Cone Penetration Instrument steel cone is pushed continuously Detection of changes in consistency, strength, and Does not acquire soil samples unless use modified tools.

Test/Seismic Cone into the ground and measures resistance to density in soils ranging from clays to finer gravel. Penetration depth may be limited due to push rig capacity in stiff Penetration Test penetration, skin friction, and other Used to estimate static undrained shear strength of soils, and the technique should not be applied to soils containing (SCPT) properties depending on devices clays, liquefaction potential of cohesionless soils, and, large amounts of cobbles.

incorporated in the cone. if so instrumented, changes in pore water pressure in saturated soils. SCPT can measure compression wave SCPT consists of a receiver to conduct velocity and shear wave velocity in soils. Experimental downhole seismic test. cone penetrometers are under development to detect various contaminants.

Field vane shear Four-bladed vane is pushed into undisturbed Used to estimate in situ undrained shear strength and Not suitable for use in silts, sands, or soils containing appreciable test soil, then rotated to cause shear failure on sensitivity of clays. amounts of gravel or shells. May yield unconservative estimates of cylindrical surface. Torsional resistance shear strength in fissured clay soils or where strength is strain-rate versus angular deflection is recorded. dependent.

Drive point Expandable steel cone is driven into soil by Detection of gross changes in consistency or relative Provides no quantitative information on soil properties.

penetrometer falling weight. Blow count versus density. May be used in some coarse-grained soils.

penetration is recorded.

Plate bearing test Steel loading plate is placed on horizontal Estimation of strength and moduli of soil. May be used Results can be extrapolated to loaded areas larger than bearing plate (soil) surface and is statically loaded, usually by at ground surface, in excavations, or in boreholes. only if properties of soil are uniform laterally and with depth.

hydraulic jack. Settlement versus time is recorded for each load increment.

Plate bearing test or Bearing pad on rock surface is statically Estimation of elastic moduli of rock masses. May be Results can be extrapolated to loaded areas larger than bearing pad Plate jacking test loaded by hydraulic jack. Deflection versus used at ground surface, in excavations, in tunnels, or in only if rock properties are uniform over volume of interest, and if (rock) load is recorded. boreholes. diameter of bearing pad is larger than average spacing of joints or other discontinuities.

Pressure meter test Uniform radial pressure is applied Estimation of elastic moduli of rocks and estimation of Test results represent properties only of materials in vicinity of (Dilatometer test) hydraulically over a length of borehole shear strengths and compressibility of soils by borehole. Results may be misleading in testing materials whose several times its diameter. Change in empirical relationships. properties may be anisotropic.

diameter versus pressure is recorded.

RG 1.132, Appendix C, Page C-4

APPENDIX C, Contd.

METHOD PROCEDURE APPLICABILITY LIMITATIONS

Field pumping test Water is pumped from or into an aquifer at Estimation of in situ permeability of soils and rock Apparent permeability may be greatly influenced by local features.

constant rate through penetrating well. mass. Effective permeability of rock is dependent primarily on frequency Change in piezometric level is measured at and distribution of joints. Test result in rock is representative only well and at one or more observation wells. to the extent that the borehole intersects a sufficient number of Pumping pressures and flow rates are joints to be representative of the joint system of the rock mass.

recorded. Packers may be used for pump-in pressure tests.

Borehole field Water is added to an open-ended pipe casing Rough approximation of in situ permeability of soils Pipe casing must be carefully cleaned out just to the bottom of the permeability test sunk to desired depth. With constant head and rock mass. casing. Clear water must be used or tests may be grossly tests, constant rate of gravity flow into hole misleading. Measurement of local permeability only.

and casing pipe are measured. Variations include applied pressure tests and falling head tests.

Direct shear test Block of in situ rock is isolated to permit Measurement of shearing resistance of rock mass in Tests are costly. Usually, variability of rock mass requires a shearing along a preselected surface. Normal situ. sufficient number of tests to provide statistical control.

and shearing loads are applied by jacking.

Loads and displacements are recorded.

Pressure tunnel test Hydraulic pressure is applied to sealed-off Determination of elastic constants of the rock mass in Volume of rock tested is dependent on tunnel diameter. Cracking length of circular tunnel, and diametral situ. caused by tensile hoop stresses may affect apparent stiffness of deformations are measured. rock.

Radial jacking test Radial pressure is applied to a length of Same as pressure tunnel test. Same as pressure tunnel test.

circular tunnel by flat jacks. Diametral deformations are measured.

Borehole jack test Load is applied to wall of borehole by two Determination of elastic modulus of rock in situ. Apparent stiffness may be affected by development of tension diametrically opposed jacks. Deformations Capable of applying greater pressure than cracks.

and pressures are recorded. dilatometers.

Borehole Device for measuring diameters is placed in Measurement of absolute stresses in situ. Stress field is affected by borehole. Analysis subject to limitations deformation meter borehole, and hole is overcored to relieve of elastic theory. Two boreholes at different orientations are stresses on annular rock core with required for determination of complete stress field. Questionable deformation meter. Diameters (usually 3) results in rocks with strongly time-dependent properties.

are measured before and after overcoring.

Rock modulus is measured by laboratory tests on core; in situ stresses are computed by elastic theory.

RG 1.132, Appendix C, Page C-5

APPENDIX C, Contd.

METHOD PROCEDURE APPLICABILITY LIMITATIONS

Inclusion Rigid stress-indicating device (stressmeter) Measurement of absolute stresses in situ. Does not Same as above.

stressmeter is placed in borehole, and the hole is require accurate knowledge of rock modulus.

overcored to relieve stresses on annular core with stress meter. In situ stresses are computed by elastic theory.

Borehole strain Strain gauge is cemented to bottom of Measurement of one component of normal stress in Stress field affected by excavation or tunnel used. Interpretation of gauge borehole, and gauge is overcored to relieve situ. Does not require knowledge of rock modulus. test results subject to assumption that loading and unloading moduli stresses on core containing strain gauge. are equal. Questionable results in rock with strongly Stresses are computed from resulting strains time-dependent properties.

and from modulus obtained by laboratory tests on core.

Hydraulic Fluid is pumped into sealed-off portion of Estimation of minor principal stress. Affected by anisotropy of tensile strength in rock.

fracturing test borehole with pressure increasing until fracture occurs.

Crosshole seismic Seismic signal is transmitted from source in In situ measurement of compression wave velocity and Requires deviation survey of boreholes to eliminate errors due to test one borehole to receiver(s) in other shear wave velocity in soils and rocks. deviation of holes from vertical. Refraction of signal through borehole(s), and transit time is recorded. adjacent high-velocity beds must be considered.

Uphole/downhole Seismic signal is transmitted between In situ measurement of compression wave velocity and Apparent velocity obtained is time average for all strata between seismic test borehole and ground surface, and transit shear wave velocity in soils and rocks. source and receiver.

time is recorded.

P-S-suspension log A 7-meter probe contains a source and two Measurement of shear and compression wave Results represent only the material immediately adjacent to the receivers spaced 1 meter apart, suspended velocities for soil and rock continuously along the borehole.

by a cable. The source generates a pressure borehole.

wave in the borehole fluid. The pressure wave is converted to seismic waves (P and S) at the borehole wall, and the P and S

waves are then converted back to pressure waves in the fluid and received by the geophones. The transit time over the gauge length is recorded as the difference in arrival times at the receivers.

Three-dimensional Logging tool contains transmitting and Measurement of compression wave and shear wave Results represent only the material immediately adjacent to the velocity log receiving transducer separated by fixed velocities in rock. Detection of void spaces, open borehole. Can be obtained only in uncased, fluid-filled borehole.

gauge length. Signal is transmitted through fractures, and zones of weakness. Correction required for variation in hole size. Use is limited to rock adjacent to borehole, and wave train at materials with P-wave velocity greater than that of borehole fluid.

receiver is recorded.

RG 1.132, Appendix C, Page C-6

APPENDIX C, Contd.

METHOD PROCEDURE APPLICABILITY LIMITATIONS

Electrical resistivity Apparent electrical resistivity of soil or rock Appropriate combination of resistivity logs can be Can be obtained only in uncased boreholes. Hole must be fluid log in neighborhood of borehole is measured by used to estimate porosity and degree of water filled, or electrodes must be pressed against borehole. Apparent in-hole logging tool containing one of a saturation in rocks. In soils, may be used as qualitative resistivity values are strongly affected by changes in hole diameter, wide variety of electrode configurations. indication of changes in void ratio or water content for strata thickness, resistivity contrast between adjacent strata, correlation of strata between boreholes and for resistivity of drilling fluid, etc.

location of strata boundaries.

Neutron log Neutrons are emitted into rock or soil Correlation of strata between boreholes and location of Because of very strong borehole effects, results are generally not of around borehole by a neutron source in the strata boundaries. Provides an approximation to water sufficient accuracy for quantitative engineering uses.

logging tool. A detector, isolated from the content and can be run in cased or uncased, source, responds to either slow neutrons or fluid-filled, or empty boreholes.

secondary gamma rays. Response of detector is recorded.

Gamma-gamma log Gamma rays are emitted into rock around Estimation of bulk density in rock, qualitative Effects of borehole size and density of drilling fluid must be (density log) the borehole by a source in the logging tool, indication of changes of density in soils. May be run in accounted for. Presently not suitable for qualitative estimate of and a detector isolated from the source empty or fluid-filled holes. density in soils other than those of rock-like character. Cannot be responds to back-scattered gamma rays. used in cased boreholes.

Response of detector is recorded.

Borehole cameras Film-type or television camera in a suitable Detection and mapping of joints, seams, cavities, or Results are affected by any condition that impairs visibility.

protective container is used for observation other visually observable features in rock. Can be used of walls of borehole. in empty uncased holes or in boreholes filled with clear water.

Borehole televiewer A rotating acoustic signal illuminates the Detection and mapping of joints, seams, cavities, or Transparency of borehole fluid is not essential.

borehole wall, and reflected signals are other observable features in rock. Can be used in recorded. mud-filled boreholes.

RG 1.132, Appendix C, Page C-7

APPENDIX D

SPACING AND DEPTH OF SUBSURFACE EXPLORATIONS

FOR FOUNDATIONS OF SAFETY-RELATED1 ENGINEERED STRUCTURES

STRUCTURE SPACING OF BORINGS2 OR SOUNDINGS MINIMUM DEPTH OF PENETRATION

General For favorable, uniform geologic conditions, where The depth of borings should be determined on the basis of the type of structure continuity of subsurface strata is found, the and geologic conditions. All borings should be extended to a depth sufficient to recommended spacing is as indicated for the type of define the site geology and to sample all materials that may swell during structure. At least three borings should be at locations excavation, may consolidate subsequent to construction, may be unstable under within the footprint of every safety-related structure, earthquake loading, or whose physical properties would affect foundation unless other reliable information is available in the behavior or stability. Where soils are very thick, the maximum required depth immediate vicinity or otherwise justifiable. Where for engineering purposes, denoted dmax, may be taken as the depth at which the variable conditions are found, spacing should be change in the vertical stress during or after construction for the combined smaller, as needed, to obtain a clear picture of soil or foundation loading is less than 10% of the effective in situ overburden stress. It rock properties and their variability. Where cavities or may be necessary to include in the investigation program several borings to other discontinuities of engineering significance may establish the soil model for soil-structure interaction studies. These borings may occur, the normal exploratory work should be be required to penetrate depths greater than those required for general supplemented by borings or soundings at a spacing engineering purposes. Borings should be deep enough to define and evaluate small enough to detect such features. the potential for deep stability problems at the site. Generally, all borings should extend at least 10 meters (m) (33 feet (ft)) below the lowest part of the foundation. If competent rock is encountered at lesser depths than those given, borings should penetrate to the greatest depth where discontinuities or zones of weakness or alteration can affect foundations and should penetrate at least 6 m

(20 ft) into sound rock. For weathered shale or soft rock, depths should be as for soils.

1 As determined by the final locations of safety-related structures and facilities.

2 Includes shafts or other accessible excavations that meet depth requirements.

RG 1.132, Appendix D, Page D-1

APPENDIX D, Contd.

STRUCTURE SPACING OF BORINGS2 OR SOUNDINGS MINIMUM DEPTH OF PENETRATION

Buildings, Principal borings: one boring at the center of At least one-fourth of the principal borings and a minimum of one boring per retaining walls, safety-related structures and additional borings along structure to penetrate into sound rock or to a depth equal to dmax. Others to a concrete dams the periphery, at corners, and other selected locations. depth below foundation elevation equal to the width of structure or to a depth For larger, heavier structures, such as the containment equal to the width of the structure or to a depth equal to the foundation depth and auxiliary buildings, at least one boring per 900 m2 below the original ground surface, whichever is greater.3

(10,000 ft2) (approximately 30 m (100 ft) spacing). One boring per 30 m (100 ft) for essentially linear structures.

Earth dams, Principal borings: one per 30 m (100 ft) along axis of Principal borings: one per 60 m (200 ft) to dmax. Others should penetrate all dikes, levees, structure and at critical locations perpendicular to the strata whose properties would affect the performance of the foundation. For embankments axis to establish geological sections with ground water water-impounding structures, to sufficient depth to define all aquifers and zones conditions for analysis.2 of underseepage that could affect the performance of structures.2 Deep cuts,4 Principal borings: one per 60 m (200 ft) along the Principal borings: one per 60 m (200 ft) to penetrate into sound rock or to dmax.

canals alignment and at critical locations perpendicular to the Others to a depth below the bottom elevation of excavation equal to the depth alignment to establish geologic sections with ground of cut or to below the lowest potential failure zone of the slope.2 Borings should water conditions for analysis.2 penetrate pervious strata below which ground water may influence stability.2 Pipelines Principal borings: This may vary depending on how Principal borings: for buried pipelines, one of every three to penetrate sound well site conditions are understood from other plant site rock or to dmax. Others to 5 times the pipe diameters below the elevation. For borings. For variable conditions, one per 30 m (100 ft) pipelines above ground, depths as for foundation structures.2 for buried pipelines; at least one boring for each footing for pipelines above ground.

Tunnels Principal borings: one per 30 m (100 ft)2; may vary for Principal borings: one per 60 m (200 ft) to penetrate into sound rock or to dmax.

rock tunnels, depending on rock type and characteristics Others to 5 times the tunnel diameter below the invert elevation.2,3 and planned exploratory shafts or adits.

3 Also supplementary borings or soundings that are design dependent or necessary to define anomalies, critical conditions, etc.

4 Includes temporary cuts that would affect ultimate site safety.

RG 1.132, Appendix D, Page D-2

APPENDIX D, Contd.

STRUCTURE SPACING OF BORINGS2 OR SOUNDINGS MINIMUM DEPTH OF PENETRATION

Reservoirs, Principal borings: In addition to borings at the locations Principal borings: at least one-fourth to penetrate that portion of the saturation impoundments of dams or dikes, a number of borings should be used to zone that may influence seepage conditions or stability. Others to a depth of investigate geologic conditions of the reservoir basin. 7.5 m (25 ft) below reservoir bottom elevation.2 The number and spacing of borings should vary, with the largest concentration near control structures and the coverage decreasing with distance upstream.

Sounding = An exploratory penetration below the ground surface used to measure or observe an in situ property of subsurface materials, usually without recovery of samples or cuttings.

Principal boring = A borehole used as a primary source of subsurface information. It is used to explore and sample all soil or rock strata penetrated to define the site geology and the properties of subsurface materials. Not included are borings from which no samples are taken, borings used to investigate specific or limited intervals, or borings so close to others that information obtained represents essentially a single location.

RG 1.132, Appendix D, Page D-3

APPENDIX E

APPLICATIONS OF SELECTED GEOPHYSICAL METHODS

FOR DETERMINATION OF ENGINEERING PARAMETERS

GEOPHYSICAL BASIC

METHOD MEASUREMENT APPLICATION ADVANTAGES LIMITATIONS

Surface Refraction (seismic) Travel time of Velocity determination of Rapid, accurate, and relatively In saturated soils, the compression wave velocity reflects compressional waves compression wave through economical technique. Interpretation mostly wave velocities in the water and thus is not through subsurface subsurface. Depths to contrasting theory generally straightforward and indicative of soil properties.

layers interfaces and geologic equipment readily available.

correlation of horizontal layers.

Reflection (seismic) Travel time of Mapping of selected reflector Rapid, thorough coverage of given site In saturated soils, the compression wave velocity reflects compressional waves horizons. Depth determinations, area. Data displays highly effective. mostly wave velocities in the water and thus is not reflected from subsurface fault detection, discontinuities, indicative of soil properties.

layers and other anomalous features.

Rayleigh wave (surface Travel time and period of Inference of shear wave velocity Rapid technique that uses conventional Coupling of energy to the ground may be inefficient, wave) dispersion surface Rayleigh waves in near-surface materials. refraction seismographs. restricting extent of survey coverage. Data resolution and penetration capability are frequency dependent; sediment layer thickness and/or depth interpretations must be considered approximate. The data interpretation model needs to be verified and validated.

Vibratory (seismic) Travel time or Inference of shear wave velocity Controlled vibratory source allows Coupling of energy to the ground may be inefficient, wavelength of surface in near-surface materials. selection of frequency, hence restricting extent of survey coverage. Data resolution and Rayleigh waves wavelength and depth of penetration [up penetration capability are frequency dependent; sediment to 60 meters (m) (200 feet (ft)]. Detects layer thickness and/or depth interpretations must be low-velocity zones underlying strata of considered approximate.

higher velocity. Accepted method.

Reflection profiling Travel times of Mapping of various lithologic Surveys of large areas at minimal time Data resolution and penetration capability is frequency (seismic-acoustic) compressional waves horizons; detection of faults, and cost; continuity of recorded data dependent; sediment layer thickness and/or depth to through water and buried stream channels, and salt allows direct correlation of lithologic reflection horizons must be considered approximate unless subsurface materials and domes, location of buried man- and geologic changes; correlative true velocities are known; some bottom conditions amplitude of reflected made objects; and depth drilling and coring can be kept to a (e.g., organic sediments) prevent penetration; water depth signal determination of bedrock or other minimum. should be at least 5 to 6 m (15 to 20 ft) for proper system reflecting horizons. operation.

RG 1.132, Appendix E, Page E-1

APPENDIX E, Contd.

GEOPHYSICAL BASIC

METHOD MEASUREMENT APPLICATION ADVANTAGES LIMITATIONS

Surface (Continued)

Electrical resistivity Electrical resistance of a Complementary to refraction Economical nondestructive technique. Lateral changes in calculated resistance often interpreted volume of material (seismic). Quarry rock, ground Can detect large bodies of soft incorrectly as depth related; hence, for this and other between probes water, and sand and gravel materials. reasons, depth determinations can be grossly in error.

prospecting. River bottom studies Should be used in conjunction with other methods, and cavity detection. i.e., seismic.

Acoustic (resonance) Amplitude of Traces (on ground surface) Rapid and reliable method. Must have access to some cavity opening. Still in acoustically coupled lateral extent of cavities. Interpretation relatively straightforward. experimental stage; limits not fully established.

sound waves originating Equipment readily available.

in an air-filled cavity Ground-penetrating radar Travel time and Rapidly profiles layering Very rapid method for shallow site Transmitted signal rapidly attenuated by water. Severely amplitude of a reflected conditions. Stratification, dip, investigations. Online digital data limits depth of penetration. Multiple reflections can electromagnetic wave water table, and presence of processing can yield on site look. complicate data interpretation. Generally performs poorly many types of anomalies can be Variable density display highly in clay-rich sediments.

determined. effective.

Gravity Variations in Detects anticlinal structures, Provided extreme care is exercised in Requires specialized personnel. Anything having mass can gravitational field buried ridges, salt domes, faults, establishing gravitational references, influence data (buildings, automobiles, etc.). Data and cavities. reasonably accurate results can be reduction and interpretation are complex. Topography and obtained. strata density influence data.

Magnetic Variations of earths Determines presence and location Minute quantities of magnetic materials Only useful for locating magnetic materials. Interpretation magnetic field of magnetic or ferrous materials are detectable. highly specialized. Calibration on site extremely critical.

in the subsurface. Locates ore Presence of any ferrous objects near the magnetometer bodies. influences data.

Uphole/downhole Vertical travel time of Determines velocity of vertical Rapid technique useful to define Care must be exercised to prevent undesirable influence of (seismic) compressional and/or P- and/or S-waves. Identifies low- velocity strata. Interpretation grouting or casing.

shear waves low-velocity zones. straightforward.

Crosshole (seismic) Horizontal travel time of Determines velocity of horizontal Generally accepted as producing reliable Careful planning with regard to borehole spacing based compressional and/or P- and/or S-waves. Elastic results. Detects low-velocity zones upon geologic and other seismic data is an absolute shear waves characteristics of subsurface provided borehole spacing is not necessity. Snells law of refraction must be applied to strata can be calculated. excessive. establish zoning. A borehole deviation survey must be run.

Requires highly experienced personnel. Repeatable source required.

RG 1.132, Appendix E, Page E-2

APPENDIX E, Contd.

GEOPHYSICAL BASIC

METHOD MEASUREMENT APPLICATION ADVANTAGES LIMITATIONS

Borehole spontaneous Natural earth potential Correlates deposits, locates water Widely used, economical tool. Log must be run in a fluid-filled, uncased boring. Not all potential resources, studies rock Particularly useful in the identification influences on potentials are known.

deformation, assesses of highly porous strata (sand, etc.).

permeability, and determines ground water salinity.

Single-point resistivity Strata electrical In conjunction with spontaneous Widely used, economical tool. Log Strata resistivity difficult to obtain. Log must be run in a resistance adjacent to a potential, correlates strata and obtained simultaneous with spontaneous fluid-filled, uncased boring. Influenced by drill fluid.

single electrode locates porous materials. potential.

Long and short-normal Near-hole electrical Measures resistivity within a Widely used, economical tool. Influenced by drill fluid invasion. Log must be run in a resistivity resistance radius of 40 to 165 centimeters fluid-filled, uncased boring.

(16 to 64 inches).

Lateral resistivity Far-hole electrical Measures resistivity within a Less drill fluid invasion influence. Log must be run in a fluid-filled, uncased boring.

resistance radius of 6 m (20 ft). Investigation radius limited in low-moisture strata.

Induction resistivity Far-hole electrical Measures resistivity in air- or Log can be run in a nonconductive Large, heavy tool.

resistance oil-filled holes. casing.

Borehole imagery Sonic image of borehole Detects cavities, joints, fractures Useful in examining casing interior. Highly experienced operator required. Slow log to obtain.

(acoustic) wall in borehole wall. Determines Graphic display of images. Fluid clarity Probe awkward and delicate.

attitude (strike and dip) of immaterial.

structures.

Continuous sonic Time of arrival of P- and Determines velocity of P- and Widely used method. Rapid and Shear wave velocity definition questionable in (three-dimensional) S-waves in high-velocity S-waves in near vicinity of relatively economical. Variable density unconsolidated materials and soft sedimentary rocks. Only velocity materials borehole. Potentially useful for display generally impressive. P-wave velocities greater than 1,500 meters per second cavity and fracture detection. Discontinuities in strata detectable. (m/s) (5,000 ft/s) can be determined.

Modulus determinations.

Sometimes S-wave velocities are inferred from P-wave velocity.

Natural gamma radiation Natural radioactivity Lithology, correlation of strata, Widely used, technically simple to Borehole effects, slow logging speed, cannot directly may be used to infer operate and interpret. identify fluid, rock type, or porosity. Assumes clay permeability. Locates clay strata minerals contain potassium-40 isotope.

and radioactive minerals.

Gamma-gamma density Electron density Determines rock density of Widely used. Can be applied to Borehole effects, calibration, source intensity, and subsurface strata. quantitative analyses of engineering chemical variation in strata affect measurement precision.

properties. Can provide porosity. Radioactive source hazard.

RG 1.132, Appendix E, Page E-3

APPENDIX E, Contd.

GEOPHYSICAL BASIC

METHOD MEASUREMENT APPLICATION ADVANTAGES LIMITATIONS

Borehole (Continued)

Neutron porosity Hydrogen content Moisture content (above water Continuous measurement of porosity. Borehole effects, calibration, source intensity, and bound table), total porosity (below Useful in hydrology and engineering water all affect measurement precision. Radioactive source water table). property determinations. Widely used. hazard.

Neutron activation Neutron capture Concentration of selected Detects elements such as U, Na, Mn. Source intensity and presence of two or more elements radioactive materials in strata. Used to determine oil-water contact (oil having similar radiation energy affect data.

industry) and in prospecting for minerals (Al, Cu).

Borehole magnetic Nuclear precession Deposition, sequence, and age of Distinguishes ages of lithologically Earth field reversal intervals under study. Still subject of strata. identical units. research.

Mechanical caliper Diameter of borehole Measures borehole diameter. Useful in a wet or dry hole. Must be recalibrated for each run. Averages 3 diameters.

Acoustic caliper Sonic ranging Measures borehole diameter. Large range. Useful with highly Requires fluid-filled hole and accurate positioning.

irregular shapes.

Temperature Temperature Measures temperature of fluids Rapid, economical, and generally None of importance.

and borehole sidewalls. Detects accurate.

zones of inflow or fluid loss.

Fluid resistivity Fluid electrical resistance Water-quality determinations and Economical tool. Borehole fluid must be same as ground water.

auxiliary log for rock resistivity.

Tracers Direction of fluid flow Determines direction of fluid Economical. Environmental considerations often preclude use of flow. radioactive tracers.

Flowmeter Fluid velocity and Determines velocity of Interpretation is simple. Impeller flowmeters usually cannot measure flows less quantity subsurface fluid flow and, in than 1-1.7 centimeters per second (2-3 ft/minute).

most cases, quantity of flow.

Borehole dipmeter Sidewall resistivity Provides strike and dip of Useful in determining information on Expensive log to make. Computer analysis of information bedding planes. Also used for location and orientation of bedding needed for maximum benefit.

fracture detection. planes and fractures over a wide variety of hole conditions.

Downhole flow meter Flow across the borehole Determines the rate and direction A reliable, cost effective method to Assumes flow not influenced by emplacement of borehole.

of ground water flow. determine lateral foundation leakage under concrete structures.

RG 1.132, Appendix E, Page E-4

APPENDIX F

IN SITU TESTING METHODS

Table F-1 In Situ Tests for Rock and Soil (adapted from EM 1110-1-1804, U.S. Army Corps of Engineers, 2001)

APPLICABILITY TO

PURPOSE OF TEST TYPE OF TEST SOIL ROCK

Shear strength Standard penetration test X

Field vane shear X

Cone penetrometer test X

Direct shear X

Plate bearing or jacking X Xa Borehole direct shearb X

b Pressuremeter X

b Uniaxial compressive X

b Borehole jacking X

Bearing capacity Plate bearing X Xa Standard penetration X

Stress conditions Hydraulic fracturing X X

Pressuremeter X Xa Overcoring X

Flatjack X

Uniaxial (tunnel) jacking X X

b Borehole jacking X

b Chamber (gallery) pressure X

Mass deformability Geophysical (refraction) X X

Pressuremeter or dilatometer X Xa Plate bearing X X

Standard penetration X

Uniaxial (tunnel) jacking X X

b Borehole jacking X

b Chamber (gallery) pressure X

Relative density Standard penetration X

In situ sampling X

b Cone penetration X

Liquefaction susceptibility Standard penetration X

Cone penetration test X

Shear wave velocity (vs) X

a. Primarily for clay shales, badly decomposed, or moderately soft rocks, and rock with soft seams.

b. Less frequently used.

RG 1.132, Appendix F, Page F-1

APPENDIX F, Contd.

Table F-2 In Situ Tests to Determine Shear Strength (adapted from EM 1110-1-1804, U.S. Army Corps of Engineers, 2001)

FOR

TEST SOILS ROCKS REMARKS

Standard X Use as index test only for strength. Develop local correlations.

penetration Unconfined compressive strength in tons/square foot) is often 1/6 to

1/8 of N-value.

Direct shear X X Expensive. Use when representative undisturbed samples cannot be obtained.

Field vane shear X Use strength reduction factor.

Plate bearing X X Evaluate consolidation effects that may occur during test.

Uniaxial X Primarily for weak rock. Expensive since several sizes of specimens compression must be tested.

Cone penetration X Consolidated undrained strength of clays. Requires estimate of test bearing factor, Nc.

Table F-3 In Situ Tests to Determine Stress Conditions (adapted from EM 1110-1-1804, U.S. Army Corps of Engineers, 2001)

TEST SOILS ROCKS REMARKS

Hydraulic fracturing X Only for normally consolidated or slightly consolidated soils Hydraulic fracturing X Stress measurements in deep holes for tunnels Vane shear X Only for recently compacted clays, silts and fine sands (see Blight,

1974,1 for details and limitations)

Overcoring X Usually limited to shallow depth in rock techniques Flatjacks X

Uniaxial (tunnel) X X May be useful for measuring lateral stresses in clay shales and rocks, jacking also in soils Pressuremeter X

(Menard)

1 Blight, G.E., Indirect Determination of in situ Stress Ratios in Particulate Materials, Proceedings of a Specialty Conference, Subsurface Explorations for Underground Excavation and Heavy Construction, American Society of Civil Engineers, New York, 1974.

RG 1.132, Appendix F, Page F-2

APPENDIX F, Contd.

Table F-4 In Situ Tests to Determine Deformation Characteristics (adapted from EM 1110-1-1804, U.S. Army Corps of Engineers, 2001)

FOR

TEST SOILS ROCKS REMARKS

Geophysical X X For determining dynamic Youngs Modulus, E, at the small strain refraction, induced by test procedure. Test values for E must be reduced to values crosshole and corresponding to strain levels induced by structure or seismic loads.

downhole Pressuremeter X X Consider test as possibly useful but not fully evaluated. For soils and soft rocks, shales, etc.

Chamber test X X

Uniaxial (tunnel) X X

jacking Flatjacking X

Borehole jack or X

dilatometer Plate bearing X

Plate bearing X

Standard X Used in empirical correlations to estimate settlement of footings; a penetration number of relationships are published in the literature to relate penetration test blow counts to settlement potential.

RG 1.132, Appendix F, Page F-3

APPENDIX G

INSTRUMENTS FOR MEASURING GROUND WATER PRESSURE

INSTRUMENT TYPE ADVANTAGES LIMITATIONSa Observation well Can be installed by drillers without participation of Provides undesirable vertical connection between strata and is geotechnical personnel. therefore often misleading; should rarely be used. Should not be confused with monitoring well.

Open standpipe piezometer Reliable. Long, successful performance record. Slow response to changes in piezometric head. Subject to damage Self-de-airing if inside diameter of standpipe is adequate. by construction equipment and by vertical compression of soil Integrity of seal can be checked after installation. Can be around standpipe. Extension of standpipe through embankment fill converted to diaphragm piezometer. Can be used for interrupts construction and causes inferior compaction. Porous filter sampling ground water. Can be used to measure can plug from repeated water inflow and outflow. Push-in versions permeability. subject to several potential errors.

Twin-tube hydraulic piezometer Inaccessible components have no moving parts. Reliable. Application generally limited to long-term monitoring of pore water Long, successful performance record. When installed in fill, pressure in embankment dams. Elaborate terminal arrangements integrity can be checked after installation. Piezometer cavity needed. Tubing must not be significantly above minimum can be flushed. Can be used to measure permeability. piezometric elevation. Periodic flushing may be required. Attention to many details is necessary.

Pneumatic piezometer Short time lag. Calibrated part of system accessible. Attention must be paid to many details when making selection.

Minimum interference to construction: level of tubes and Push-in versions subject to several potential errors.

readout independent of level of tip. No freezing problems.

Vibrating wire piezometer Easy to read. Short time lag. Minimum interference to Special manufacturing techniques required to minimize zero drift.

construction: level of lead wires and readout independent of Need for lightning protection should be evaluated. Push-in version level of tip. Lead wire effects minimal. Can be used to read subject to several potential errors.

negative pore water pressures. No freezing problems.

a. Diaphragm piezometer readings indicate the head above the piezometer, and the elevation of the piezometer must be measured or estimated if piezometric elevation is required. All diaphragm piezometers, except those provided with a vent to the atmosphere, are sensitive to barometric pressure changes.

RG 1.132, Appendix G, Page G-1

APPENDIX G, Contd.

INSTRUMENT TYPE ADVANTAGES LIMITATIONSa Electrical resistance piezometer Easy to read. Short time lag. Minimum interference to Low electrical output. Lead wire effects. Errors caused by moisture, construction: level of lead wires and readout independent of temperature, and electrical connections are possible. Long-term level of tip. Suitable for dynamic measurements. Can be used stability uncertain. Need for lightning protection should be to read negative pore water pressures. No freezing problems. evaluated. Push-in version subject to several potential errors.

Multipoint piezometer, with packers Provides detailed pressure-depth measurements. Can be Limited number of measurement points. Other limitations depend installed in horizontal or upward boreholes. Other advantages on type of piezometer: See above in table.

depend on type of piezometer: See above in table.

Multipoint piezometer, surrounded with Provides detailed pressure-depth measurements. Simple Limited number of measurement points. Applicable only in uniform grout installation procedure. Other advantages depend on type of clay of known properties. Difficult to ensure in-place grout of piezometer: See above in table. known properties. Other limitations depend on type of piezometer:

See above in table.

Multipoint push-in piezometer Provides detailed pressure-depth measurements. Simple Limited number of measurement points. Subject to several potential installation procedure. Other advantages depend on type of errors. Other limitations depend on type of piezometer: See above in piezometer: See above in table. table.

Multipoint piezometer, with movable Provides detailed pressure-depth measurements. Unlimited Complex installation procedure. Periodic manual readings only.

probe number of measurement points. Allows determination of permeability. Calibrated part of system accessible. Great depth capability. Westbay Instruments system can be used for sampling ground water and can be combined with inclinometer casing.

RG 1.132, Appendix G, Page G-2