{{#Wiki_filter:PROBABILISTIC SEISMIC HAZARD EVALUATION AND UNIFORM HAZARD SPECTRA St.Lucie and Turkey Point Nuclear Power Plant Sites FLORIDA Report prepared for the Florida Power 8 Light Company Nuclear Licensing Department December 1989 9107260135 910719 PDR ADOCK 05000250 P PDR EBASCO EBASCO SERVICES INCORPORATED Greensboro, N.C.

Qi~~Ch I TABLE OF CONTENTS 1.0 2.0 3.0 4.0 5.0 6.0 7.0 5.1 5.2 5.3 Summary Introduction Review of EPRI Seismic Hazard Investigations The EPRI Computer Programs for Seismic Hazard Analysis Input Data Seismic Source Zones Seismicity Parameters Attenuation Equations Hazard Computation Hazard Results Page 1-1 2-1 3-1 4-1 5-1 5-1 5-2 5-2 6-1 7-1'.0 7.1 St.Lucie 7.1.1 Peak Ground Acceleration (PGA)7.1.2 Pseudo Relative Velocity at 25 hz 7.1.3 Pseudo Relative Velocity at 10 hz 7.1.4 Pseudo Relative Velocity at 5 hz 7.1.5 Pseudo Relative Velocity at 2.5 hz 7.1.6 Pseudo Relative Velocity at 1 hz 7.1.7 Uniform Hazard Spectra Turkey Point 7.2.1 Peak Ground Acceleration (PGA)7.2,2 Pseudo Relative Velocity at 25 hz 7.2.3 Pseudo Relative Velocity at 10 hz 7.2.4 Pseudo Relative Velocity at 5 hz 7.2.5 Pseudo Relative Velocity at 2.5 hz 7.2.6 Pseudo Relative Velocity at 1 hz 7.2.7 Uniform Hazard Spectra Conclusions 7-1 7-1 7-2 7-2 7-3 7-4 7-5 7-5 7-5 7-6 7-7 7-8 7-8 7-9 7-10 8-1 9.0 References 9-1 g II II I I I Appendix A-Quality Assurance for the adaptation of EPRI's EQHAZ and EQPOST Programs A.1 EQHAZ Program A.2 EQPOST Program Page A-1 A-1 A-1 Appendix B-Contribution of Northern Caribbean Sources to Seismic Hazard B.O Definition of Northern Caribbean Source Zones B.1 Tectonics of the Northern Caribbean Region B.2 Relationship of Earthquakes to Faults and Subduction Zones B.3 Seismic Source Zones of the Northern Caribbean B.3.1 The Cayman Trough Source Zone B.3.2 The Jamaica-Western Hispaniola Source Zone B.3.3 The Eastern Hispaniola Source Zone B.3.4 The Puerto Rico Trench Source Zone B.3.5 The Muertos Trough Source Zone B.3.6 The Greater Antilles-Lesser Antilles Transition Source Zone B.4 Estimation of Recurrence Relations for the Northern Caribbean Sources B.S Estimation of Maximum Magnitude Earthquakes B.6 Results of Seismic Hazard Calculations for the Northern Caribbean Sources B-1 B-1 B-1 B-2 B-3 B-4 8-4 B-5 B-6 B-6 B-7 B-8 B-9 Appendix C.1 C.2 C.3 C.4 C.5 C-Site Specific AmpliGcation for St.Lucie Site Location and Physiography Regional Stratigraphy Site Stratigraphy Properties of Subsurface Materials Foundation Conditions C-1 C-1 C-1 C-2 C-3 C-3 Appendix D.1 D.2 D.3 D.4 D-Site Specific Amplification for Turkey Point Site Location and Physiography Regional Stratigraphy Site Stratigraphy Properties of Subsurface Materials D-1 D-1 D-1 D-2 D-3  

The probabilistic seismic hazard at St.Lucie and Turkey Point Sites is very low.Most of the contribution to the St.Lucie and Turkey Point sites, in the case of each of the TEC source zones, is derived from the background source containing the sites.In summary, the results of the probabilistic seismic hazard evaluation for Florida Power and Lights St.Lucie and Turkey Point sites, using the EPRI methodology, yield very low V values for each site's seismic hazard.The results of seismic hazard computations are discussed in Section 7.1-2 I I TABLE 1-1 St.Lucie Annual Probability of Exceedance for Peak Ground Acceleration (PGA)PGA PGA (cm/sec)(g)Mean 15 Percentiles 50 85 7.00 65.00 120.00 225.00 400.00 560.00 800.00 0.007 0.07 0.12 0.23 0.41 0.57 0.82 7.36E-04 3.89E-05 1.24E-05 1.61E-06 1.78E-07 5.08E-OS 1.22E-OS 1.82E-05 7.80E-07 2.00E-07 1.40E-08 5.82E-10 1.97E-10 1.91E-10 4.97E-04 3.15E-05 1.05E-05 1.04E-06 7.48E-08 1.32E-08 1.51E-09 1.60E-03 6.84E-05 2.29E-05 2.75E-06 3.08E-07 8.60E-08 1.41E-08 TABLE 1-2 Turkey Point Annual Probability of Exceedance for Peak Ground Acceleration (PGA)PGA PGA (cm/sec2)(g)Mean 15 Percentiles 50 85 5.00 50.00 100.00 250.00 500.00 700.00 1000.00 0.005 0.05 0.10 0.26 0.51 0.71 1~02 3.90E-03 3.18E-05 1.08E-05 1.39E-06 1.52E-07 4.33E-OS 1.04E-OS 1.02E-04 7.89E-07 1.87E-07 1.29E-OS 7.26E-10 3.91E-10 3.91E-10 3.27E-04 2.75E-05 9.57E-06 9.19E-07 5.95E-08 9.89E-09 1.17E-09 1.34E-02 5.61E-05 2.02E-05 2.58E-06 2.85E-07 7.16E-08 1.21E-08

+Mean Hazard 10 O<C C)LLI Ld~1O LLI I l l I 1 1 l'L 1 l l 1 l-5 CQ<C CO O-6 10<C Z-7<1O 8 I+.+=+-.10-9 10 0.0 0.2 0.4 0.6 0.8 1.0 ACCELERATION (g)Florida Power and Light Company EBASCO SERVICES INCORPORATEO FIGURE 1.1 I I I 100 50th Percentile Uniform Hazard Spectra ST.LUCIE O 10 IJJ V)C3 O 0 1 LLj-5 1.0410-4 1.0+10-4.2.0410-3 1.0810 0.1 0.01 0.1 PERIOD (SEC)10 Florida Power and Light Company EBASCO SERVICES INCORPORATEO FIGURE 1-2 II II I I I 100 Mean Uniform Hazard Spectra ST.LUCIE V 10 V)C3-5 1.0810 1.0+10 4 2.0810-3 1.0+10 2.0410 C3 0 1 e)0.1 0.01 0.1 PERIOD (SEC)10 Florida Power and Light Company EBASCO SERVICES INCORPORATEO FIGURE 14 I I I 10 HAZARD RESULTS AT TURKEY POINT EQUAL TEAM WEIGHTS-2 10-3 10 O<C C)LLI LLI OC V 10 LLI I l l I I I I I I I 1 l l I l 0 85th Percentile 50th Percentile 15th Percentile

+Mean Hazard-5 CO<C CCI D-6 10 Z-7 K 10 10 10 0.0 0.2 0.4 0.6 ACCELERATION (g)0.8 1.0 Florida Power and Light Company EBASCO SERVICES INCORPORATEO FIGURE 14

~~II Ill 5 II a~~II 100 50th Percentile Uniform Hazard Spectra TURKEY POINT 10 LLI V)C3 0 1 LLI-5 1.0410-4 1.0+10 4 2.0410-3 1.0~10 3 2.0410 0.1 0.01~0.1 PERlOO (SEC)10 C Florida Power and Light Company EBASCO SERVICES INCORPORATEO FIGURE 1.5 Q

100 Mean Uniform Hazard Spectra TURKEY POINT O 10 V)O-5 1.0>>10 4 1.0+10 4 2.0810-3 1.0410-3 2.0+10 O 0 1 LLj 0.1 0.01 0.1 PERiOD (SE:C)10 Florida Power and Light Company EBASCO SERVICES INCORPORATEO FIGURE 14 I  

The earth's crust is comprised of a series of plates which are in motion relative to each other.Along present day plate boundaries, such as the vicinity of V.S.west coast, strain accumulates at relatively high rates.Consequently, the mean return period for large earthquakes in these areas is on the order of tens or in some cases hundreds of years.By contrast, deformation in the interior areas of plates, such as the Eastern United States, occurs at much slower rates, resulting in lower levels of seismicity.

In these regions, the return period between moderate to large seismic events may be on the order of thousands or perhaps even tens of thousands of years.A review of historical seismicity occurring in the Eastern U.S.reveals that the overall level of Eastern U.S.seismicity is relatively low, consistent with its setting.However, at some locations, such as New Madrid, Missouri and Charleston, South Carolina the levels of historical and/or instrumental seismicity are relatively high.The 1811-12 New Madrid earthquakes and the 1886 Charleston earthquake stand out as the most significant events to occur in the Eastern V.S.during historical times.Consequently the cause of these earthquakes and the potential for similar large events occurring elsewhere in the region must be addressed during the development of seismic design criteria for critical facilities.

To date the criteria used by the NRC in establishing seismic design values for nuclear facilities in the Eastern United States as outlined in Appendix A to 10 CFR Part 100 require that seismicity be correlated with a tectonic structure or in the absence of such a seismogenic structure be correlated with a specific tectonic province.Based in part on the opinions expr'essed by the AEC and the U.S.G.S.in the late 1960's and early 1970's, the NRC has taken the position that seismicity occurring in the New Madrid and Charleston areas are related to tectonic structures unique to the epicentral areas of the 1811-1812 and 1886 events, and for the purposes of seismic design, the occurrence of similar large earthquakes outside these areas is not considered credible.2-1 I I I Since the early 1970's, multidisciplinary investigations of the tectonics and seismicity of the Eastern U.S.have been carried out with the goal of understanding the cause of Eastern seismicity, thus leading to a better comprehension of the seismic hazard in the region.Based on these studies various models have been put forward to explain Eastern U.S.seismicity.

In addition, the scope of the ESI investigation included an evaluation of the contribution to seismic hazard at the St.Lucie and Turkey Point sites from the possible occurrence of large magnitude earthquakes in the Northern Caribbean.

2-3 I I 8+St.Lucie Turkey Point Key to Site Index Numbers"Srtes considered by LLNL to fallin the Southeastern Region of the tJS.1.Limerick" 2.Shearon Harris'.Braidwood 4.La Crosse 5.River Bend 6.Wolf Creek 7.Watts Bar'.Vogtle'.Millstone 10.Maine Yankee Florida Power and Light Company EBASCO SERVICES IIICORPORATEO Location of the LLNL Sample Sites and St.Lucie and Turkey Point FIGURE 2-1 Il I I 3.0 REVIEW OF EPRI SEISMIC HAZARD INVESTIGATIONS As noted the Electric Power Research Institute (EPRI)implemented a probabilistic seismic hazard evaluation in parallel to the NRC funded studies.The main objectives of the EPRI program were to: 1)compile from existing sources a data base consisting of geological, tectonic, geophysical, and seismological information suitable for evaluating the physical significance and applicability of causative models for earthquake generation in the Eastern U.S.2)develop interpretative seismic source zones for moderate and large earthquakes in the Eastern U.S.3)develop seismicity parameters for the zones 4)estimate the probabilities of activity for each zone 5)assess the uncertainty in the seismicity parameters for each zone.The resulting information could be used to assess the seismic hazard for facilities in the eastern U.S..To accomplish these objectives, EPRI enlisted the services of six Technical Evaluation Contractors (TEC)to work in parallel to compile a data base and perform tectonic evaluations leading to the interpretation of seismic source zones and their associated seismicity parameters.

3-1  

Workshops were the key method of exchanging information and interpretations among the TEC.Although consensus interpretations were not required, a common understanding of competing interpretations and their technical bases were sought.The seismic hazards methodology contractor coordinated and managed the tectonic interpretation workshops.

Guidance and assistance in characterizing uncertainty and assigning weights to the alternative interpretations and their parameter values were provided to the TEC in the several workshops that were held at regular intervals 0 throughout the study.The topics covered by the various workshops included: 2)3)4)5)6)7)Inventory of tectonic models and assessment of data needs to perform tectonic evaluations, Review of data sets and initial tectonic models evaluations, Review of tectonic model evaluations Tectonic framework interpretation Review of tectonic framework and seismic source interpretation Methodology for seismicity parameter evaluation Review of seismicity parameters.

The results of the EPRI study were published in a series of documents comprised of m workshop proceedings, reports on the seismic hazard methodology, and reports on the tectonic framework and seismic source zones of the Eastern U.S.by the six TEC.(EPRI, 1986 and 1987).3-2 I I I I I I 4.0 THE EPRI COMPUTER PROGRAMS FOR SEISMIC HAZARD ANALYSIS The EPRI computer.programs for seismic hazard analysis follow the general methodology outlined by Cornell (1968)and were derived primarily from the McGuire (1976)seismic risk program.However, the EPRI Programs differ from the McGuire Program in four main aspects: 1)In the EPRI Study, seismic sources are subdivided into one-degree cells.The"a" and"b" values can be speciGed separately for each cell, thus allowing the user to specify spatial variability in the seismicity properties of a source, 2)The EPRI Programs allow the user to specify uncertainties on the seismic source conGguration, the seismicity parameters, the upper-bound magnitudes, and the attenuation functions.

The effects of these uncertainties are kept separate so as to obtain uncertainties as well as mean values in the Qnal hazard estimates, 3)The EPRI Programs also aggregate the results obtained from the application of=the interpretations of the different TECs, and 4)The EPRI Programs perform simultaneously hazard analyses on several measures of ground motion, such as Peak Ground Acceleration (PGA), Pseudo-Spectral Relative Velocity (PSRV)for 5%damping at 1, 2.5, 5, 10 and 25 hz.The computer programs used to perform the seismic hazard computations are collectively referred to as the EQHAZARD package.EQHAZARD consists of four modules: EQPARAM: Performs analysis of the historical earthquake catalog, and calculates recurrence parameters that are allowed to vary spatially within specified seismic source geometries.

4-1 I'I I I I I I I I I I EQHAZ: Calculates the seismic hazard contribution at a given site (geographic position)for each source in the vicinity, and for multiple alternative interpretations of source parameters and multiple ground motion attenuation functions.

D Computes the total seismic hazard at a site for each set of alternative interpretations of seismic sources and source combinations.

A detailed description of the EPRI Seismic Hazard Methodology for the Central and Eastern U.S.is given in volumes 1, 2 and 3 (EPRI, 1986 and 1987).4-2 I I I I 5.0 INPUT DATA The methodology developed by the EPRI for the computation of seismic hazard was applied to the St.Lucie and Turkey Point nuclear power plant sites.A probabilistic seismic hazard analysis consists of estimating the annual probabilities that various levels of earthquake ground motions will be exceeded at a site.In the hazard computation, the following input data are needed: 1)a description of earthquake source zones and an estimation of the probability of activity of each zone, singly or in combination with other sources, 2)maximum magnitude distribution and seismicity parameter distribution for each source zone, along with their associated probabilities, for each of the six TEC, and 3)an estimation of the attenuation of ground motion between these sources and the site under investigation.

5.1 Seismic Source Zones Seismic source interpretations for the EPRI program were made independently by the six TEC teams, and collectively these sources represent the current state of scientiGc knowledge on the subject.In addition, a formal subjective probability assessment approach was developed to permit each team to express its confidence that a seismic source is the true explanation of earthquake activity, thus enabling uncertainty to be understood and quantified.

Uncertainty was considered in terms of the state of scientific knowledge of earthquake causes and characteristics, and in terms of limitations imposed by an incomplete data base.The method also allows speciGcation of dependencies among sources.For example, if two sources represent dif'ferent structures which cannot be activated at the same time, this aspect of the source behavior becomes part of the source representation.

If there are uncertainties in the boundary of a source, it can also be accommodated by using a set of possible alternative boundaries.

A subjective probability is assigned to each alternate source geometry representing the likelihood that it is the correct source conGguration.

5-1 I I I I I I I I The seismic source zones that were used in the seismic hazard evaluation for the St.Lucie and Turkey Point Sites are grouped by TEC and listed in Table 5-1.The location and extent of these seismic source zones are shown on Figures 5-1 through 5-6.The probability of activity of these sources, their interdependencies, the maximum magnitude distribution, and the choices of smoothing options given by the six TEC for calculation of seismicity parameters are given in the EQHAZARD Primer (EPRI, 1989).Some of the Caribbean sources of high seismicity are closer to the sites than the Charleston or New Madrid sources.This is especially true for the Turkey Point site.Consequently, we investigated the tectonics of the Northern Caribbean region to delineate seismic source zones (Figure 5-7)and develop associated seismicity parameters.

for that region (Appendix B).These data were then used to evaluate the hazard at the sites from earthquakes in the Northern Caribbean.

5.2 Seismicity Parameters Seismicity parameters were developed for each source configuration separately.

To'model the statistical occurrence of future earthquakes within a source, EPRI utilized two approaches:

one that specifies spatially uniform activity within a source, and the other that allows for spatial variation of activity within a source.The flexibility of the second approach offers the advantage of representing variations in earthquake occurrence over a large region.5.3 Attenuation Equations EPRI adopted the following standard form of the attenuation equation to characterize ground motion from a given earthquake magnitude m~and hypocentral distance R in kilometer.

ln y=a+b m~+c ln R+d R 5-2 I I I I I I I I I I where a, b, c, and d are coefficients derived by theoretical or empirical methods.The equation predicts the mean of the natural logarithm of y, the ground motion parameter (spectral velocity in cm/sec, or acceleration in cm/sec').The uncertainty in ground motion is incorporated in the seismic hazard analysis by considering multiple attenuation models.Weights may be assigned to each model by experts, based on the credibility that is given to the hypothesis that it is the"true" ground motion.In the EPRI/SOG hazard computations for nuclear power plant sites in the eastern U.S.the following three attenuation models were used.1)The attenuation f'unctions derived by McGuire et al.(1988), using a aqua'red model with stress drop of 100 bars.weight: 0.50 2)The attenuation functions computed by Boore and Atkinson (1987), using a ar squared model with stress drop of 100 bars.weight: 0.25 3)Nuttli (1986)attenuation model combined with the Newmark and Hall (1982)response spectral shape.weight: 0.25 The first two of these models are based on a random-vibration method, which utilizes a source scaling model, a random-process representation of acceleration, and a simplified representation of propagation effects.The coefficients in the above empirical attenuation equation are summarized in Table 5-2.f A standard error of 0.50 in ln y was assumed for all models in the hazard computations.

5-3 I I I I I I I Table 5-1 Computerized Data Base Label No.of Source Zones TEC Name TEC Label No.(Used on TEC Maps)Source Name Data Base Label No.(Used on Computer Files)Bechtel Group Dames&Moore 13 30 31 H N-3 BZ-0 BZ-1 BZ-4 20 21 22 22-21B 52 53 54 65 Mesozoic Basins New Madrid Reelfoot Rift Charleston Area Charleston Faults New Madrid Region Gulf Coast Background Atlantic Coast Background Southern Coastal Margin New Madrid Reelfoot Rift Reelfoot Rift-New Madrid Charleston Rift Southern Appalachian Default Charleston Seismic Zone Dunbarton Triassic Basin 01300 03000 03100 05200 05900 00100 00600 02000 02000'02100 02200 91500 05200 05300 05400 06500 Law Engineering 04a 04b 22 08 18 35 108 126 M-37 M-38 M-39 M-40 M-41 M-42 M-43 M-44 M-45 M-48 M-49 M-50 Reelfoot Rift(A)Reelfoot Rift(B)Reactivated Eastern Seaboard Mesozoic Basins Reelfoot Rift Faults Charleston Brunswick Background.

TABLE 6-1 Contributing Source Zones TEC Team St Lucie Turke Point Bechtel 01300, 05200, 00600, 02000, CB001 CB002 00600, 02000, CB001, CB002 Dames and Moore Law Engineering 00816, 06001, 03849 CB002 02200, 03842 03850 04300, 03848 CB001, 02000, 05200, 05300, 05400, CB001 CB002 02000, t 05400 00816, 06001, CB001, 05200 05300 CB001, CB002 02200, 04300, 03842 03848 CB002 Rondout Associates Weston Geophysical Corporation Woodward Clyde Consultants 02400, 02600, 04905, 05100, CB001 CB002 02500, 02600, 05400, 05700, 92000, 92100, 92200, 92300, 92400, 92700, 92800, CB001, CB002 02900, 0290A, WCCBK CB001 CB002 02400 02600, 04905, 05100, CB001, CB002 02500 02600 05400 05700, 92000 92100 92200 92300 92400 CB002 02900 0290A, WCCBK CB001, CB002 Notes: Source Zone numbers correspond to those on Table 4-1 CB001 and CB002 are northern Caribbean Seismic Sources described in Appendix B (see also Section 8.0)The contributions of the underlined sources to the peak ground acceleration, PSV at 25-and 10 hz were small.

I I I I I I I I TABLE 6-2 Scenarios for Contributing Source Zonesl St.Lucie (frequencies greater than 5hz)TEC Team Bechtel Scenario2 00600+02000+01300+05200 00600+02000+01300 00600+02000+05200 00600+02000 W~e5.he~0.05 0.05 0.45 0.45 Background 00600 02000 1.0 1.0 Dames and Moore 02000+05400 02000+05400+05200 02000+05400+05300 0.28 0.46 0.26 Background 02000 1.0 Law Engineering

02400+02600+04905+05100 04905 05100 1.0 1.0 1.0 Wes ton Geophysical Corporation 05700+92000 05700+02500+92100 05700+02600+92200 05700+02600+92300 05700+02500+92400 05700+02500+92700 05700+02600+92800 05700+05400 0.001 0.012 0.069 0.312 0.368 0.126 0.100 0.012 Background 05700 1.0 Woodward Clyde Consultants

WCCBK WCCBK+02900 WCCBK+0290A WCCBK 0,573 0.122 0.305 1.0 Table 6-2-continued I I I I I I I I TABLE 6-2 (continued)

Scenarios for Contributing Source Zones St.Lucie (frequencies 5hz and less)~TEE Tee Bechtel Scenario2 00600+02000+01300+05200+CB001+CB002 00600+02000+01300+CB001+CB002 00600+02000+05200+CB001+CB002 00600+02000+CB001+CB002 W~ei htE 0.05 0.05 0.45 0.45 Background 00600 02000 1.0 1.0 Dames and Moore 02000+05400+CB001+CB002 02000+05400+05200+CB001+CB002 02000+05400+05300+CB001+CB002 0.28 0.46 0.26 Background 02000 1.0 Law Engineering 04300+06001+02200+CB001+CB002 04300+06001+00816+03842+03848+03849+03850+CB001+CB002 04300+06001+00816+CB001+CB002 04300+06001+03842+03848+03849+03850+CB001+CB002 04300+06001+CB001+CB002 0.2700 0.1161 0.1539 0.1978 0.2622 Background 04300 06001 0'2 0.49 Rondout Associates 02400+02600+04905+05100+CB001+CB002 1.0 Background 04905 05100 1.0 1.0 Weston Geophysical Corporation 05700+92000+CB001+CB002 05700+02500+92100+CB001+CB002 05700+02600+92200+CB001+CB002 05700+02600+92300+CB001+CB002 05700+02500+92400+CB001+CB002 05700+02500+92700+CB001+CB002 05700+02600+92800+CB001+CB002 05700+05400+CB001+CB002 O.OO1 0.012 0.069 0.312 0.368 0.126 0.100 0.012 Background 05700 1.0 Table 6-2-continued  

Scenarios for Contributing Source Zones St.Lucie (frequencies 5hz and less)TEC Team Scenario2 W~ei he~Woodward Clyde Consultants

~WCCBK+CB001+CB002 WCCBK+02900+CB001+CB002 WCCBK+0290A+CB001+CB002 0.573 0.122 0.305 Background WCCBK 1.0 Notes: Source Zone numbers correspond to those on Table 1 and on Figures 2 through 7.Each TEC scenario is made up of the allowable source zone combinations whose total weights, or probability of activity add up to 1.0.Weight is defined as the fractional probability of activity.

I I I I I I I I TABLE 6-3 Scenarios for Contributing Source Zones Turkey Point (frequencies greater than 5hz)TEC Team Bechtel Scenario2 00600+02000+CB001+CB002 W~ei he3 1.0 Background 00600 02000 1.0 1.0 Dames and Moore 02000+CB001+CB002 1.0 Law Engineering