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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.

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.

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

control number.

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-

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.

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.

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.

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.

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.

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.

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

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.

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.

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.

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

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.

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.

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.

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.

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.

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.

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.

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.

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

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.

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.

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.

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 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.

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.

(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.

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.

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.

(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.

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.

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.

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.

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.

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.

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.

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.

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

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.

(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.

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.

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.

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.

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.

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.

(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.

(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.

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.

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

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===

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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.

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.

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, Management Directive 8.4, Washington, DC.

Solution during life of structure may be damaging.

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

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