HomeMy WebLinkAboutSUP 06-10X2A; AGUA HEDIONDA OUTER LAGOON MAINTENANCE; AGUA HEDIONDA OUTER LAGOON FLOOD SHOAL MAINTENANCE DREDGING SEDIMENT SAMPLING AND ANALYSIS PLAN 2017-2018; 2017-12-01
CABRILLO POWER I LLC, AGUA HEDIONDA LAGOON
OUTER LAGOON FLOOD SHOAL MAINTENANCE DREDGING
SEDIMENT SAMPLING AND ANALYSIS PLAN 2017‐2018
ACOE #2001‐00328‐RRS
Prepared for:
Cabrillo Power I LLC
4600 Carlsbad Boulevard
Carlsbad, CA 92009‐4301
Prepared by:
Merkel & Associates, Inc.
5434 Ruffin Road
San Diego, CA 92123
Phone: (858) 560‐5465
Fax: (858) 560‐7779
December 2017
December 2017
Merkel & Associates, Inc. #14‐051‐06 i
TABLE OF CONTENTS
1.0 INTRODUCTION..................................................................................................................................1
2.0 BACKGROUND....................................................................................................................................1
3.0 TESTING PROGRAM............................................................................................................................7
3.1 Core Logging and Sample Handling................................................................................................9
3.2 Physical and Chemical Analyses...................................................................................................11
4.0 REPORT PREPARATION.....................................................................................................................16
5.0 REFERENCES.....................................................................................................................................17
LIST OF FIGURES
Figure 1. Proposed Beach and Lagoon Sampling Stations...........................................................................8
Figure 2. Lagoon Sampling Stations on Preliminary 2017 Bathymetry......................................................10
LIST OF TABLES
Table 1. Percent sand composition from prior shoal pre‐dredging testing programs. ...............................2
Table 2. 2014 grain size and TOC results. ....................................................................................................2
Table 3. 2014 sediment chemistry results...................................................................................................3
Table 4. Proposed sample locations at tidal basin and receiver location....................................................9
Table 5. Chemical and physical analyses for sediment samples................................................................12
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CABRILLO POWER I LLC, AGUA HEDIONDA LAGOON
OUTER LAGOON FLOOD SHOAL MAINTENANCE DREDGING
SEDIMENT SAMPLING AND ANALYSIS PLAN
ACOE #2001‐00328‐RRS(UNDER RENEWAL)
December 2017
1.0 INTRODUCTION
This Sampling and Analysis Plan (SAP) is for the characterization of flood shoal sediment deposits within
the outer basin of Agua Hedionda Lagoon. Maintenance shoal removal and beach replenishment are
proposed to occur under ACOE IP #2001‐00328‐RRS and are part of an on‐going maintenance dredging
program at the site. Dredging is completed every two to three years as required by shoal development.
Under permit, up to 500,000 cubic yards (cy) of sediment may be dredged per maintenance interval.
The dredging is all maintenance littoral sand removal with no cuts into native sediments. The material is
to be removed by suction cutterhead dredge and placed on coastal beaches outside of the lagoon.
While beach placement is not proposed to the north of the ocean inlet in 2017‐2018 dredge cycle (North
Carlsbad State Beach) and would be limited to the Middle and South Carlsbad State Beaches, sampling
on North Beach will still occur to provide overall context of sediment conditions within the littoral cell.
Mapping of the adjacent nearshore habitat areas indicates the sand discharge area is very dynamic with
areas experiencing annual erosion and accretion of sand beaches and movement of sand both long‐
shore and offshore through time (M&A 2017).
This SAP details the sediment collection and testing program to be conducted on the proposed dredged
material in accordance with the standard procedures outlined in conditions of ACOE IP #2001‐00328‐
RRS, Evaluation of Dredged Material Proposed for Discharge in Waters of the U.S. (Inland Testing
Manual [ITM]) (EPA/USACE 1998) and regional guidance of the USACE regulatory branch (USACE 1991).
These guidance documents apply to inland waters, near‐coastal waters, and surrounding environs.
2.0 BACKGROUND
The outer basin (Outer Lagoon) of Agua Hedionda Lagoon is an efficient sediment trap for entrained
littoral sand that is brought into the lagoon through the combined influence of tidal circulation and
cooling water flows. Sediment accumulation in the flood shoal of the lagoon degrades the tidal prism
and tidal flushing within the lagoon and also reduces the operational efficiency of the power plant
located on the outer basin. Since initial lagoon dredging in 1954, the accumulated flood shoal sand has
been dredged out every one to three years to maintain an open tidal connection with limited muting of
the lagoon. Previous testing of the flood shoal has indicated that the shoal is comprised exclusively of
beach sand (Table 1).
During the most recent dredging sediment‐testing program (2014), grain size analyses indicated the
material was composed of 98.1 to 99.3 percent (%) sand (Table 1), and total organic carbon (TOC) values
ranged from 0.03 to 0.04%. Coincident with this, receiver beaches were found to have a sand content
ranging from 95.1 to 100% across the various sampling years. Receiver beach TOC samples in 2014
ranged between 0.02 and 0.03% (M&A 2014).
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Table 1. Percent sand composition from prior shoal pre‐dredging testing programs.
Year Percent Sand Source
1993 95.5%‐97.5% MEC 1993
1995 96.0%‐98.9% MEC 1995
1997 93.8%‐98.0% MEC 1997
2000 98.4%‐98.7% MEC 2000
2002 90.0%‐97.1% MEC 2002
2004 97.4%‐98.9% MEC‐Weston 2004
2006 97.9%‐98.7% Weston 2006
2008 97.7%‐99.2% M&A 2008
2010 97.2%‐98.5% M&A 2010
2014 98.1%‐99.3% M&A 2014
In 2014, the California State Lands Commission requested a verification testing of the shoal sand
chemistry in conjunction with issuance of a new long‐term lease (Lease No. 932.1) allowing the
placement of Agua Hedionda Lagoon maintenance dredged materials on to the beach. While the nature
of the source material and physical characteristics of the sand are not conducive to be carriers of
contaminants, testing was conducted for this verification purpose in July 2014. The same shoal area has
been recurrently dredged was tested using the same sampling stations distributed through the shoal (L‐
1 through L‐3). In addition for beach compatibility, grain size and TOC was determined for the receiver
beach (RB‐1 through RB‐3). Sediment grain size characteristics and TOC continued to reveal the littoral
sand nature of the shoal (Table 2).
Table 2. 2014 grain size and TOC results.
Sample
Location Gravel (%) Sand (%) Silt (%) Clay (%)
Mean
Particle Size
(mm)
TOC (%)
L‐1 0.0 99.3 0.5 0.2 0.45 0.04%
L‐2 0.0 98.9 0.8 0.3 0.37 0.03%
L‐3 0.0 98.1 1.6 0.4 0.27 0.04%
Average 0.0 98.8 1.0 0.3 0.36 0.04%
RB‐1 0.0 100.0 0.0 0.0 0.35 0.03%
RB‐2 0.0 98.9 0.8 0.3 0.38 0.02%
RB‐3 0.0 99.1 0.6 0.3 0.26 ND
Average 0.0 99.4 0.4 0.1 0.33 ‐‐
ND = Not Detected
There were very few chemicals of concern detected within the collected sediments; and when detected,
concentrations were at low levels falling below established effects range median (ERM) and effects
range low (ERL) guideline values, where such levels have been determined (Table 3). ERL and ERM
values were developed as sediment quality guidelines to determine the potential for chemical
contaminants in the sediment to cause adverse environmental effects (Buchman 2008; Long et al. 1995).
The ERL is the lowest tenth percentile concentration of the available sediment toxicity data, and
represents a concentration below which effects to sensitive species are not expected to occur. The ERM
is the median effects concentration, above which adverse effects are likely to occur.
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Table 3. 2014 sediment chemistry results.
Compound Parameter Units ERL ERM L‐1 L‐2 L‐3
Antimony mg/kg ND ND ND
Arsenic mg/kg 8.2 70 0.785 0.673 1.06
Barium mg/kg 11.2 15.7 31.9
Beryllium mg/kg ND ND ND
Cadmium mg/kg 1.2 9.6 ND ND ND
Chromium mg/kg 81 370 2.42 3.39 6.51
Cobalt mg/kg 0.737 1.06 1.92
Copper mg/kg 34 270 1.17 1.7 3.05
Lead mg/kg 46.7 218 0.536 0.697 0.925
Mercury mg/kg 0.15 0.71 ND ND ND
Molybdenum mg/kg ND ND ND
Nickel mg/kg 20.9 51.6 0.992 1.45 2.33
Selenium mg/kg ND ND ND
Silver mg/kg 1 3.7 ND ND ND
Thallium mg/kg ND 0.037 0.087
Vanadium mg/kg 5.33 7.73 13.9
Metals
Zinc mg/kg 150 410 8.82 13.5 20.0
Aldrin μg/kg ND ND ND
Alpha‐BHC μg/kg ND ND ND
Beta‐BHC μg/kg ND ND ND
Delta‐BHC μg/kg ND ND ND
Gamma‐BHC μg/kg ND ND ND
Chlordane μg/kg ND ND ND
Dieldrin μg/kg 0.02 8 ND ND ND
Trans‐nonachlor μg/kg ND ND ND
2,4'‐DDD μg/kg ND ND ND
2,4'‐DDE μg/kg ND ND ND
2,4'‐DDT μg/kg ND ND ND
4,4'‐DDD μg/kg 2 20 ND ND ND
4,4'‐DDE μg/kg 2.2 27 ND ND ND
4,4'‐DDT μg/kg 1 7 ND ND ND
Total Detectable DDTs μg/kg 1.58 46.1
Endosulfan I μg/kg ND ND ND
Endosulfan II μg/kg ND ND ND
Endosulfan Sulfate μg/kg ND ND ND
Endrin μg/kg ND ND ND
Endrin Aldehyde μg/kg ND ND ND
Chlorinated
Pesticides
Endrin Ketone μg/kg ND ND ND
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Table 3. 2014 sediment chemistry results (continued).
Compound Parameter Units ERL ERM L‐1 L‐2 L‐3
Heptachlor μg/kg ND ND ND
Heptachlor Epoxide μg/kg ND ND ND
Methoxychlor μg/kg ND ND ND
Toxaphene μg/kg ND ND ND
Alpha Chlordane μg/kg ND ND ND
Gamma Chlordane μg/kg ND ND ND
Cis‐nonachlor μg/kg ND ND ND
Chlorinated
Pesticides
Oxychlordane μg/kg ND ND ND
1,6,7‐
Trimethylnaphthalene μg/kg ND ND ND
1‐Methylnaphthalene μg/kg ND ND ND
1‐Methylphenanthrene μg/kg ND ND ND
2‐Methylnaphthalene μg/kg 70 670 ND ND ND
2,6‐
Dimethylnaphthalene μg/kg ND ND ND
Acenaphthene μg/kg 16 500 ND ND ND
Acenaphthylene μg/kg 44 640 ND ND ND
Anthracene μg/kg 85.3 1100 ND ND ND
Benzo (a) Anthracene μg/kg 261 1600 ND ND ND
Benzo (a) Pyrene μg/kg 430 1600 ND ND ND
Benzo (b) Fluoranthene μg/kg ND ND ND
Benzo (e) Pyrene μg/kg ND ND ND
Benzo (g,h,i) Perylene μg/kg ND ND ND
Benzo (k) Fluoranthene μg/kg ND ND ND
Benzoic Acid μg/kg ND ND ND
Biphenyl μg/kg ND ND ND
Chrysene μg/kg 384 2800 ND ND ND
DCPA μg/kg ND ND ND
Dibenz (a,h) Anthracene μg/kg 63.4 260 ND ND ND
Dibenzothiophene μg/kg ND ND ND
Fluoranthene μg/kg 600 5100 ND ND ND
Fluorene μg/kg 19 540 ND ND ND
Indeno (1,2,3‐c,d)
Pyrene μg/kg ND ND ND
Isophorone μg/kg ND ND ND
Naphthalene μg/kg 160 2100 ND ND ND
Perthane μg/kg ND ND ND
Perylene μg/kg ND ND ND
PAHs
Phenanthrene μg/kg 240 1500 ND ND ND
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Table 3. 2014 sediment chemistry results (continued).
Compound Parameter Units ERL ERM L‐1 L‐2 L‐3
Pyrene μg/kg 665 2600 ND ND ND PAHs Total PAHs μg/kg 4022 44792
2,3,4,6‐
Tetrachlorophenol μg/kg ND ND ND
2,4,5‐Trichlorophenol μg/kg ND ND ND
2,4,6‐Trichlorophenol μg/kg ND ND ND
2,4‐Dichlorophenol μg/kg ND ND ND
2,4‐Dimethylphenol μg/kg ND ND ND
2,4‐Dinitrophenol μg/kg ND ND ND
2,6‐Dichlorophenol μg/kg ND ND ND
2‐Chlorophenol μg/kg ND ND ND
2‐Methylphenol μg/kg ND ND ND
2‐Nitrophenol μg/kg ND ND ND
3/4‐Methylphenol μg/kg ND ND ND
4,6‐Dinitro‐2‐
Methylphenol μg/kg ND ND ND
4‐Chloro‐3‐
Methylphenol μg/kg ND ND ND
4‐Nitrophenol μg/kg ND ND ND
Pentachlorophenol μg/kg ND ND ND
Phenols
Phenol μg/kg ND ND ND
Bis(2‐Ethylhexyl)
Phthalate μg/kg 13 11 14
Butyl Benzyl Phthalate μg/kg 6.6 6.1 18
Diethyl Phthalate μg/kg ND ND ND
Dimethyl Phthalate μg/kg 240 370 400
Di‐n‐Butyl Phthalate μg/kg ND ND ND
Phtalates
Di‐n‐Octyl Phthalate μg/kg ND ND ND
PCB003 μg/kg ND ND ND
PCB008 μg/kg ND ND ND
PCB018 μg/kg ND ND ND
PCB028 μg/kg ND ND ND
PCB031 μg/kg ND ND ND
PCB033 μg/kg ND ND ND
PCB037 μg/kg ND ND ND
PCB044 μg/kg ND ND ND
PCB049 μg/kg ND ND ND
PCB052 μg/kg ND ND ND
PCB056 μg/kg ND ND ND
PCBs
PCB060 μg/kg ND ND ND
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Table 3. 2014 sediment chemistry results (continued).
Compound Parameter Units ERL ERM L‐1 L‐2 L‐3
PCB066 μg/kg ND ND ND
PCB070 μg/kg ND ND ND
PCB074 μg/kg ND ND ND
PCB077 μg/kg ND ND ND
PCB081 μg/kg ND ND ND
PCB087 μg/kg ND ND ND
PCB095 μg/kg ND ND ND
PCB097 μg/kg ND ND ND
PCB099 μg/kg ND ND ND
PCB101 μg/kg ND ND ND
PCB105 μg/kg ND ND ND
PCB110 μg/kg ND ND ND
PCB114 μg/kg ND ND ND
PCB118 μg/kg ND ND ND
PCB119 μg/kg ND ND ND
PCB123 μg/kg ND ND ND
PCB126 μg/kg ND ND ND
PCB128 μg/kg ND ND ND
PCB132 μg/kg ND ND ND
PCB138/158 μg/kg ND ND ND
PCB141 μg/kg ND ND ND
PCB149 μg/kg ND ND ND
PCB151 μg/kg ND ND ND
PCB153 μg/kg ND ND ND
PCB156 μg/kg ND ND ND
PCB157 μg/kg ND ND ND
PCB167 μg/kg ND ND ND
PCB168 μg/kg ND ND ND
PCB169 μg/kg ND ND ND
PCB170 μg/kg ND ND ND
PCB174 μg/kg ND ND ND
PCB177 μg/kg ND ND ND
PCB180 μg/kg ND ND ND
PCB183 μg/kg ND ND ND
PCB184 μg/kg ND ND ND
PCB187 μg/kg ND ND ND
PCB189 μg/kg ND ND ND
PCBs
PCB194 μg/kg ND ND ND
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Table 3. 2014 sediment chemistry results (continued).
Compound Parameter Units ERL ERM L‐1 L‐2 L‐3
PCB195 μg/kg ND ND ND
PCB200 μg/kg ND ND ND
PCB201 μg/kg ND ND ND
PCB203 μg/kg ND ND ND
PCB206 μg/kg ND ND ND
PCB209 μg/kg ND ND ND
PCBs
Total PCB Congeners μg/kg 22.7 180
Notes:
All results reported as dry weight.
Bold Text – Exceeds ERL
Bold and Underlined Text – Exceeds ERM
ND = not detected above the reporting limit. Some analytes are reported that were detected at a concentration
below the reporting limit and above the laboratory method detection limit. See Eurofins report in Appendix C for
all estimated values.
mg/kg ‐ milligram per kilogram, μg/kg ‐ micrograms per kilogram, ERL ‐ Effects Range Low, ERM ‐ Effects Range
Median, DDT – dichlorodiphenyltrichloroethane, PAH ‐ polycyclic aromatic hydrocarbons, PCB ‐ polychlorinated
biphenyls
The conditions of the lagoon remain substantively unchanged from those existing during the 2014
sediment‐testing program and the chemical testing performed provided a refreshed verification that the
sand in the shoal is clean sediment. In addition, M&A has worked extensively within Agua Hedionda
Lagoon in association with the recent eradication of the invasive alga Caulerpa taxifolia from the system
and subsequent eelgrass surveys. As a result, M&A staff members have first hand information regarding
lagoon conditions and believe there is no reason to suspect any change in sediment conditions from
those occurring in prior sampling events.
3.0 TESTING PROGRAM
Sediment testing is proposed in accordance with the requirements of regulatory permits and the
“Evaluation of Dredge Material Proposed for Discharge in Waters of the U.S. – Testing Manual” (Inland
Testing Manual) (Environmental Protection Agency (EPA)/U.S. Army Corps of Engineers (USACE) 1998).
Merkel & Associates, Inc. (M&A), under contract to Cabrillo Power I LLC, will manage the sediment
collection and testing study.
This study will include the following elements:
Preparation of this SAP;
Collection of sediment samples to project depth according to the procedures outlined in the
SAP;
Physical analyses on flood shoal and receiver beach samples, and chemical analyses on
composite flood shoal and receiver beach samples, and;
Data analysis and report preparation.
Sampling locations for the maintenance dredging of the outer lagoon and the receiver beaches follow
the distribution of effort for prior testing events (Figure 1).
Beach Receiving Station
\\' Beach and Lagoon Sampling Stations Figure 1
s ...__ _____________________________ Merl<e/ & Associates, Inc. __ __.
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Samples are to be collected by continuous core through the accumulated sands. Samples will be taken
to the proposed dredge depth plus 2‐feet of over dredge. The target core depth will be 24 ft from a top
elevation of the flood shoal at approximately 0 foot MLLW for two cores (L1 and L2) to be collected
within the sand trap at the lagoon mouth with a design depth of ‐22 feet MLLW. An additional core (L3)
will be collected to a design depth of ‐17 feet MLLW plus 2‐feet of over‐dredge. This core is also located
on the shoal with a top elevation of ‐1 foot MLLW (Figure 2). Lagoon core sample distribution (L1 ‐ L3)
has been determined such that each continuous core represents approximately one third of the dredge
material volume to be removed. Cores will be taken to the target depth or depth of refusal.
Coordinates and target penetration are shown for each proposed sampling location in Table 4. Actual
sampled locations shall be recorded to a ±3 meter accuracy using GPS.
Receiver beaches are to be sampled at high (+5 to +7 feet MLLW) and low (‐2 to +1 feet MLLW) intertidal
elevations. Samples shall consist of surface sands collected by using a 6‐inch deep hand core. Beach
samples shall be collected from Carlsbad State Beach at the north (RB‐1), middle (RB‐2), and south (RB‐
3) beaches where material is to be placed. Note that the current dredge cycle does not include disposal
at the north receiver area; however, a sediment sample will be collected from RB‐1 for physical analyses
only (grain size and TOC). Proposed sampling coordinates for beach sites are provided in Table 4.
Table 4. Proposed sample locations at tidal basin and receiver location.
Site Approx.
Volume (yd3)
Sample
Location Longitude Latitude Target Penetration
(ft)
L‐1 117o 20’33” 33o 08’45” 24
L‐2 117o 20’29” 33o 08’41” 24
Shoal
(Outer
Lagoon )
350,000
L‐3 117o 20’24” 33o 08’38” 18
RB‐1* 117o 20’55” 33o 08’59” 0.5
RB‐2 117o 20’29” 33o 08’30” 0.5 Receiver Site
(Beach)
RB‐3 117o 20’19” 33o 08’13” 0.5
*RB‐1 will be sampled and analyzed for grain size only. It will not be included in the composite chemical analyses.
3.1 CORE LOGGING AND SAMPLE HANDLING
Core samples will be carefully extruded onto clean, plastic trays, photographed, and observed for unique
strata, color, odors, etc. These observations, along with information on weather, currents, tides, winds,
and other site conditions, will be recorded in the field log. The following information will be recorded
during the sediment collection program in a project‐specific field log:
Date and time of collection
Sample identification code
Sampling location (latitude/longitude to within a 3‐meter accuracy)
Water depth or elevation (± 0.1 ft)
Tidal stage and currents
Climatic conditions
Sampling method and any problems encountered
Core penetration/core recovery
Description of the material type obtained in the samples (color, odor, etc.)
Description of any vertical stratification in each core
Description of sediment subsampling methods if any required
Lagoon Sampling Stationson Preliminary 2017 BathymetryEncina Power Station - Agua Hedionda Lagoon 2017-2018 Agua Hedionda Lagoon Maintenance Dredging
Figure 2
M&A # 14-051-06
L3
L2
L1
0
-5
-15
-10
-20
-25-30
-35
-20
-5
0
0
-5
-5
-10
-20
-5
-5
0
-15
-10
0
-10
0
-5
-15
-5
-5
0
0
-10
-20
Merkel & Associates, Inc.
-22'
-17'
-1
-2-1
1
1
LIMITS OF AUTHORIZED DREDGING
ANTICIPATED 2017-2018 DREDGE AREAS
EXISTING SURFACE
DISTANCE (FT)DEPTH ( FT MLLW)3,500
DREDGED SURFACE
L1 L2 L3
0
N
•E w
.
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Sediment stratification has not been observed in any of the prior characterizations of the flood shoal
and as such no stratification is anticipated in the present effort. As a result, a composite sample will be
collected from the entire core length. If distinct stratification greater than 2 feet is detected, then a
separate sample will be taken from the strata although will not be analyzed until results from the
composite sample are available and appears warranted. Each core sample will be thoroughly
homogenized in clean, non‐contaminating stainless steel mixing vessels and subsampled for archive
purposes.
Collected sediments shall be kept separate in individual sample containers labeled with individual
sample identification, date and time of collection and samples will be stored with ice packs at
approximately 4ºC until analyzed by the laboratory. Archived samples will be put into labeled 16 oz (500
ml) glass jars with teflon‐lined lids and frozen. Samples will be held for a period of three months
following submittal of the testing report. At which point they will be disposed of unless the client
requests transfer of the sample.
The integrity of each sample from the time of collection to the point of data reporting must be
maintained throughout the study. Proper record keeping and chain‐of‐custody procedures will be
implemented to allow samples to be traced from collection to their final disposition. After collection of
sediment, documentation on various logs and forms will be required to adequately identify and catalog
station and sample information. Field log entries will be completed at the time that observations are
made.
Sample container identification information will be recorded on the chain‐of‐custody form. The chain‐
of‐custody forms will also identify the sampling organization, point of contact, sample collection date
and time, type of sample, and project. The form will also serve as a sample analysis request form.
Samples will be sent to the laboratory along with a chain‐of‐custody form specifying the sample
identification and the analyses to be conducted (by referencing a list of specific analyses or the
statement of work for the laboratory). These forms will be prepared in triplicate; the field supervisor
will retain one copy, and the other 2 copies will accompany the shipment.
Proper completion of all chain‐of‐custody documentation will be the responsibility of the field manager.
Chain‐of‐custody forms will be completed and signed before the end of each sampling day and before
the samples are removed from the vessel or pass from the control of the field supervisor. Chain‐of‐
custody forms will be signed at each additional point of transfer of samples between the field and the
laboratory as well as within the laboratory.
Receiver beach sediments are to be collected and processed similarly to the dredge site sediments for
compatibility assessment. High and low beach samples at each site are to be composited to create a
characterization of the individual site. All samples will be processed as bulk samples with no
subsampling or stratified sampling.
3.2 PHYSICAL AND CHEMICAL ANALYSES
Eurofins Calscience, a National Environmental Laboratory (NELAP) accredited laboratory, will conduct all
physical and analytical chemical analyses. All six samples (L‐1, L‐2, L‐3, RB‐1, RB‐2, and RB‐3) will be
individually analyzed for TOC and grain size distribution. A composite lagoon sample (composed of
sediment from L‐1, L‐2, and L‐3) and a composite receiver site sample (composed of sediment from RB‐2
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and RB‐3) will be analyzed for chemistry only. The physical and chemical analyses and methods for the
samples are listed in Table 5.
The sediment chemistry results for this study will be compared to available sediment quality guidelines
(e.g., effects range low [ERLs] and effects range median [ERMs]) to determine the potential for chemical
contaminants in the sediment to cause adverse environmental effects (Buchman 2008; Long et al. 1995).
Grain size distribution data will be tabulated to evaluate sediment compatibility between proposed
nourishment material and receiver site.
Table 5. Chemical and physical analyses for sediment samples.
Compound Parameter Units Analysis Methods
Grain‐Size % ASTM D4464(M)
Percent/Total Solids % SM2540B Conventionals
Total Organic Carbon % EPA 9060A
Arsenic mg/kg
Cadmium mg/kg
Chromium mg/kg
Copper mg/kg
Lead mg/kg
Mercury mg/kg
Nickel mg/kg
Selenium mg/kg
Silver mg/kg
Metals
Zinc mg/kg
EPA 6020/6020A & 7471A
Aldrin μg/kg
Alpha‐BHC μg/kg
Beta‐BHC μg/kg
Delta‐BHC μg/kg
Gamma‐BHC μg/kg
Chlordane μg/kg
Dieldrin μg/kg
Trans‐nonachlor μg/kg
2,4'‐DDD μg/kg
2,4'‐DDE μg/kg
2,4'‐DDT μg/kg
4,4'‐DDD μg/kg
4,4'‐DDE μg/kg
4,4'‐DDT μg/kg
Total Detectable DDTs μg/kg
Endosulfan I μg/kg
Endosulfan II μg/kg
Endosulfan Sulfate μg/kg
Chlorinated
Pesticides
Endrin μg/kg
EPA 8081A
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Compound Parameter Units Analysis Methods
Endrin Aldehyde μg/kg
Endrin Ketone μg/kg
Heptachlor μg/kg
Heptachlor Epoxide μg/kg
Methoxychlor μg/kg
Toxaphene μg/kg
Alpha Chlordane μg/kg
Gamma Chlordane μg/kg
Cis‐nonachlor μg/kg
Chlorinated
Pesticides
Oxychlordane μg/kg
EPA 8081A
1,6,7‐Trimethylnaphthalene μg/kg
1‐Methylnaphthalene μg/kg
1‐Methylphenanthrene μg/kg
2‐Methylnaphthalene μg/kg
2,6‐Dimethylnaphthalene μg/kg
Acenaphthene μg/kg
Acenaphthylene μg/kg
Anthracene μg/kg
Benzo (a) Anthracene μg/kg
Benzo (a) Pyrene μg/kg
Benzo (b) Fluoranthene μg/kg
Benzo (e) Pyrene μg/kg
Benzo (g,h,i) Perylene μg/kg
Benzo (k) Fluoranthene μg/kg
Benzoic Acid μg/kg
Biphenyl μg/kg
Chrysene μg/kg
DCPA μg/kg
Dibenz (a,h) Anthracene μg/kg
Dibenzothiophene μg/kg
Fluoranthene μg/kg
Fluorene μg/kg
Indeno (1,2,3‐c,d) Pyrene μg/kg
Isophorone μg/kg
Naphthalene μg/kg
Perthane μg/kg
Perylene μg/kg
Phenanthrene μg/kg
Pyrene μg/kg
PAHs
Total PAHs μg/kg
EPA 8270C SIM
December 2017
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Table 5. Chemical and physical analyses for sediment samples. (continued).
Compound Parameter Units Analysis Methods
2,3,4,6‐Tetrachlorophenol μg/kg
2,4,5‐Trichlorophenol μg/kg
2,4,6‐Trichlorophenol μg/kg
2,4‐Dichlorophenol μg/kg
2,4‐Dimethylphenol μg/kg
2,4‐Dinitrophenol μg/kg
2,6‐Dichlorophenol μg/kg
2‐Chlorophenol μg/kg
2‐Methylphenol μg/kg
2‐Nitrophenol μg/kg
3/4‐Methylphenol μg/kg
4,6‐Dinitro‐2‐Methylphenol μg/kg
4‐Chloro‐3‐Methylphenol μg/kg
4‐Nitrophenol μg/kg
Pentachlorophenol μg/kg
Phenols
Phenol μg/kg
Bis(2‐Ethylhexyl) Phthalate μg/kg
Butyl Benzyl Phthalate μg/kg
Diethyl Phthalate μg/kg
Dimethyl Phthalate μg/kg
Di‐n‐Butyl Phthalate μg/kg
Phtalates
Di‐n‐Octyl Phthalate μg/kg
EPA 8270C SIM
PCB003 μg/kg
PCB008 μg/kg
PCB018 μg/kg
PCB028 μg/kg
PCB031 μg/kg
PCB033 μg/kg
PCB037 μg/kg
PCB044 μg/kg
PCB049 μg/kg
PCB052 μg/kg
PCB056 μg/kg
PCB060 μg/kg
PCB066 μg/kg
PCB070 μg/kg
PCB074 μg/kg
PCB077 μg/kg
PCBs
PCB081 μg/kg
EPA 8270C SIM
December 2017
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Table 5. Chemical and physical analyses for sediment samples. (continued).
Compound Parameter Units Analysis Methods
PCB087 μg/kg
PCB095 μg/kg
PCB097 μg/kg
PCB099 μg/kg
PCB101 μg/kg
PCB105 μg/kg
PCB110 μg/kg
PCB114 μg/kg
PCB118 μg/kg
PCB119 μg/kg
PCB123 μg/kg
PCB126 μg/kg
PCB128 μg/kg
PCB132 μg/kg
PCB138/158 μg/kg
PCB141 μg/kg
PCB149 μg/kg
PCB151 μg/kg
PCB153 μg/kg
PCB156 μg/kg
PCB157 μg/kg
PCB167 μg/kg
PCB168 μg/kg
PCB169 μg/kg
PCB170 μg/kg
PCB174 μg/kg
PCB177 μg/kg
PCB180 μg/kg
PCB183 μg/kg
PCB184 μg/kg
PCB187 μg/kg
PCB189 μg/kg
PCB194 μg/kg
PCB195 μg/kg
PCB200 μg/kg
PCB201 μg/kg
PCB203 μg/kg
PCB206 μg/kg
PCB209 μg/kg
PCBs
Total PCB Congeners μg/kg
EPA 8270C SIM
December 2017
Merkel & Associates, Inc. #14‐051‐06 16
Table 5. Chemical and physical analyses for sediment samples. (continued).
Compound Parameter Units Analysis Methods
Allethrin (Bioallethrin) μg/kg
Bifenthrin μg/kg
Cyfluthrin‐beta (Baythroid) μg/kg
Cyhalothrin‐Lamba μg/kg
Cypermethrin μg/kg
Deltamethrin (Decamethrin) μg/kg
Esfenvalerate μg/kg
Fenpropathrin (Danitol μg/kg
Fenvalerate (sanmarton) μg/kg
Permethrin (cis and trans) μg/kg
Fluvalinate μg/kg
Resmethrin (Bioresmethrin) μg/kg
Resmethrin μg/kg
Sumithrin (Phenothrin) μg/kg
Tetramethrin μg/kg
Pyrethroids
Tralomethrin μg/kg
EPA 8270D
4.0 REPORT PREPARATION
The draft and final study reports will contain the following information:
Introduction – Includes a project description and a history of the site, historical uses, results of
previous toxicity or sediment work, known contamination or discharges, and other relevant
information
Site Maps – Shows the test sediment collection locations
Core Log – Includes core collection coordinates, target/actual penetration, and sediment
characteristics (e.g., strata, color, odor)
Methods and Materials – Includes all information pertaining to test sediment collection,
handling, and analyses
Results – Includes results from any physical and chemical testing
Discussion – Includes a detailed description of any chemical and physical characteristics of the
test sediments
References
Photographic Documentation
Quality Assurance/Quality Control Information
December 2017
Merkel & Associates, Inc. #14‐051‐06 17
5.0 REFERENCES
Buchman, M.F. 2008. NOAA Screening Quick Reference Tables, NOAA OR&R Report 08‐1, Seattle WA,
Office of Response and Restoration Division, National Oceanic and Atmospheric Administration,
34 pages.
Environmental Protection Agency (EPA)/U.S. Army Corps of Engineers (USACE). 1998. Evaluation of
Dredged Material Proposed for Discharge in Waters of the U.S., Testing Manual: Inland Testing
Manual. EPA Reference 823‐B‐98‐004. February.
Long, E.R., D.L. MacDonald, S.L. Smith, and F.D. Calder. 1995. Incidence of Adverse Biological Effects
within Ranges of Chemical Concentration in Marine and Estuarine Sediments. Environmental
Management 19 (1): 81‐97.
MEC‐Weston, Inc. 2004. Cabrillo Power 1 LLC Agua Hedionda Lagoon Field Investigations for Outer
Lagoon Dredging, Data Report November 2004.
MEC. 2002. Agua Hedionda Lagoon, Field investigations for outer lagoon dredging. Submitted to Cabrillo
Power, October 2002.
MEC. 2002. Cabrillo Power 1 LLC Agua Hedionda Lagoon 2002 Outer Lagoon/Beach Sediment Sampling
and Analysis Plan.
MEC. 2000. Agua Hedionda Lagoon, Field investigations for outer lagoon dredging. Submitted to
Cabrillo Power, September 2000.
MEC. 1997a. Agua Hedionda Lagoon, Field investigations for middle lagoon dredging. Submitted to
SDG&E, April 1997.
MEC. 1997b. Environmental Conditions and Potential Impacts Associated With Dredging the Inner
Section of Agua Hedionda Lagoon. Submitted to SDG&E, May 1997.
MEC. 1995. SDG&E Encina Power Plant, Agua Hedionda Lagoon dredge sediment analysis. Submitted to
SDG&E, June 1995.
MEC. 1993. Field investigations for lagoon dredging. Submitted to SDG&E, November 1993.
Merkel & Associates, Inc. (M&A). 2017. 2016 Agua Hedionda Lagoon Maintenance Dredging Nearshore
Habitat Mapping. January 2017.
Merkel & Associates, Inc. (M&A). 2014. Cabrillo Power I LLC, Agua Hedionda Lagoon Outer Lagoon
Flood Shoal Maintenance Dredging Sediment Characterization Report. November 2014.
Merkel & Associates, Inc. (M&A). 2010. Cabrillo Power I LLC, Agua Hedionda Lagoon Outer Lagoon
Flood Shoal Maintenance Dredging Sediment Characterization Report. December 2010.
Merkel & Associates, Inc. (M&A). 2008. Cabrillo Power I LLC, Agua Hedionda Lagoon Outer Lagoon
Flood Shoal Maintenance Dredging Sediment Characterization Report. December 2008.