6650 SW Redwood Lane, Suite 333 Portland, Oregon 97224 Phone 503.670.1108 Fax 503.670.1128 www.anchorqea.com M EMORANDUM To: Sean Sheldrake, U.S. Environmental Date: June 20, 2014 Protection Agency From: Ryan Barth, P.E., Anchor QEA, LLC Project: 000029-02.32 Cc: Re: Bob Wyatt, NW Natural Patty Dost, Pearl Legal Group PLLC Myron Burr, Siltronic Corporation Alan Gladstone, Davis Rothwell Earle & Xóchihua P.C. James Peale, Maul Foster Alongi Lance Petersen, CDM Smith Gasco Sediments Site Distributed Temperature Sensing Work Plan This Work Plan has been prepared by Anchor QEA, LLC, on behalf of NW Natural and in coordination with Siltronic Corporation (Siltronic) for the Gasco Sediments Site, located on the Willamette River adjacent to the NW Natural Gasco and Siltronic properties in Portland, Oregon (Figure 1). NW Natural and Siltronic are developing and evaluating remedial alternatives for the Gasco Sediments Site pursuant to the Administrative Settlement Agreement and Order on Consent (AOC; Docket No. CERCLA 10-2009-0255) and the Statement of Work attached to the AOC. The purpose of this Work Plan is to describe a proposed field investigation for identifying areas of groundwater discharge and recharge in the Willamette River adjacent to the Gasco Sediment Site to support the evaluation of remedial technologies required by the AOC. OBJECTIVE The objective of the proposed investigation is to identify groundwater discharge and recharge areas within the Interim Project Area (Interim Project Area) at the Gasco Sediments Site. Groundwater flow through sediment is a potential mechanism for contaminant transport in the offshore sediments adjacent to these properties. Therefore, identification of groundwater discharge and recharge areas is important for assessing potential contaminant movement and the associated impacts on sediment remedial technology performance over time. NW Natural developed a groundwater model during development of the Draft Engineering Evaluation/Cost Analysis (EE/CA; Anchor QEA 2012) to estimate the extent of offshore
Mr. Sean Sheldrake June 20, 2014 Page 2 groundwater capture in the Willamette River during operation of the upland HC&C system. USEPA s comments on the EE/CA (EPA 2005) stated, The predictions of flow reversal from the groundwater model should be validated before the sediment remedy is finalized. This Work Plan describes a field investigation to assess offshore groundwater flow conditions now that the Hydraulic Control and Containment (HC&C) system is in operation in order to support future sediment remedial design work. The proposed field investigation targets data collection in an portion of the Interim Project Area. If the collected data is helpful in evaluating remedial effectiveness of different design scenarios in the target area, NW Natural may decide to propose implementation of this technology in other portions of the Project Area. INVESTIGATION METHOD Distributed Temperature Sensing Background Distributed temperature sensing (DTS) is a method for identifying areas of groundwater discharge and recharge based on the difference between groundwater and surface water temperatures. Surface water temperatures in the Willamette River vary widely between summer and winter. Typical high temperatures exceed 65 degrees Fahrenheit [ F], and typical low temperatures are below 45 F (Figure 2). Groundwater temperatures, by comparison, have a small variance; temperatures measured in the vicinity of the proposed test area are approximately 55 F throughout the year. During periods of significant differences between groundwater and surface water temperatures, groundwater discharge areas exhibit transition-zone water temperatures that are more similar to the temperature of the groundwater than the surface water. The DTS technology employs fiber optic cables to quantify temperature differences by exploiting a property of light transmission through glass. The DTS instrument sends pulses of light along a fiber optic cable and detects the wavelengths and timing of backscattered light. As briefly explained in the following paragraph, the wavelengths of the backscattered light indicate the temperature of the cable at the location where the backscatter occurred, and the time elapsed between sending the pulse of light and detecting the backscatter indicates the location along the cable where the backscatter occurred. The distance from the light source (DTS instrument) to the backscatter location can be calculated from a precise measurement of elapsed time because the speed of light transmission in the glass fiber is known. Light traveling along a glass fiber induces emissions of light from electrons in the glass molecules. A fraction of the light is emitted in wavelengths different from the wavelength of the incident light. This phenomenon is known as the Raman Effect. The energy state of the glass molecules, which is a function of the temperature, determines the wavelength of the light
Mr. Sean Sheldrake June 20, 2014 Page 3 emitted. Therefore, the ratio of light emitted at wavelengths lower and higher than the incident light indicates the temperature of the material at the location of the backscatter. DTS instruments are capable of measuring and recording very high-resolution data. Temperature differences of less than 0.2 F can be reliably detected. Spatial resolution can be as fine as readings at approximately every 1 foot along a glass fiber. Temporal resolution is approximately 10 minutes between readings at a given location along the glass fiber. Distributed Temperature Sensing at Contaminated Sediment Sites The DTS technology has been used to identify groundwater discharge and recharge areas at a number of contaminated sediment sites regulated by the USEPA. Pursuant to a Great Lakes Legacy Act project agreement with USEPA, Anchor QEA used DTS data to support the design of a sediment cap at the River Raisin site in Monroe, Michigan, in 2013. The DTS technology was provided and managed by the subcontractor SelkerMetrics, LLC, of Portland, Oregon. The results of the DTS investigation were used to select locations for installing seepage meters that quantify the flux of groundwater discharge and collect transition-zone water samples. The data were used to assess contaminant loading to an adsorbent cap. SelkerMetrics has also used the DTS technology for several other projects, including contaminated sediment sites in Texas and western Canada. Previous Offshore Groundwater Investigations The location for the DTS field investigation (Figure 3) was selected considering the spatial extents for the various remedial technologies presented in the EE/CA (Anchor QEA 2012) and the results of previous offshore groundwater investigations in the Interim Project Area. Seepage flux data were collected by the Lower Willamette Group in 2005 (Integral 2005 and 2006) and NW Natural in 2007 (Anchor QEA 2008). Two of the previous seepage meter locations, GS-B7SM and GCSEEP 7F, were within the DTS test area. Seepage rates at GS-B7SM ranged between -5.5 and +1.0 centimeters per day (cm/d), and seepage rates at GCSEEP 7F ranged between +5.6 and +10.0 cm/d. A negative seepage rate indicates surface water recharge to the groundwater, and a positive seepage rate indicates groundwater discharge. These data do not account for operation of the upland HC&C system, as the data collection was performed prior to installation of the system. Proposed DTS Test Investigation Figure 3 presents the DTS fiber optic cable layout for the field investigation. Approximately 1,130 feet of fiber optic cable is proposed at elevations ranging from the high water line to the edge of the federal navigation channel. In submerged areas, the cable will be deployed by a
Mr. Sean Sheldrake June 20, 2014 Page 4 diver using a hand tool to bury the cable in the top 2 inches of sediment. Anchor points will be installed within the vicinity of the locations shown in Figure 3. The DTS instrument and cable combination will be calibrated prior to collecting temperature data. The calibration procedure involves immersing lengths of the cable in temperature-controlled water baths while recording backscattered light data to adjust the interpreted temperature to the raw data using the known temperature. After calibration and deployment, temperature measurements will be collected during a period of several days and evaluated to assess the responsiveness of the equipment. In accordance with the AOC requirements, the results of the DTS field investigation will be submitted to USEPA. SCHEDULE The following table identifies the potential timing for the activities that will be conducted to implement the DTS field investigation described in this Work Plan. The DTS cable deployment is proposed during the in-water construction window, which is July 1 to October 31, 2014, so no permitting requirements are triggered. Table 1 Project Schedule Activity Potential Timeframe Project Planning April to July 2014 DTS Field Investigation DTS Cable Deployment and Calibration July/August 2014 Temperature Measurements 3-4 Weeks Following Deployment Data evaluation August/September 2014 Notes: DTS = distributed temperature sensing
Mr. Sean Sheldrake June 20, 2014 Page 5 REFERENCES Anchor QEA (Anchor QEA, LLC), 2012. Draft Engineering Evaluation/Cost Analysis. Prepared for NW Natural. May. Anchor QEA, 2008. Offshore Investigation Report NW Natural Gasco Site. Prepared for NW Natural. February. Integral Consulting, Inc., 2005. Portland Harbor RI/FS Round 2 Groundwater Pathway Assessment Sampling and Analysis Plan Attachment 1 Field Sampling Plan Groundwater Plume Discharge Mapping. Prepared for the Lower Willamette Group. July 1, 2005. Integral Consulting, Inc., 2006. Portland Harbor RI/FS Round 2 Groundwater Pathway Assessment Transition Zone Water Site Characterization Summary Report DRAFT. Prepared for the Lower Willamette Group. August 7, 2006.
FIGURES
Seattle Olympia Tacoma WASHINGTON Yakima May 19, 2014 10:07am heriksen T:\CAD\Projects\0029-NW Natural Gas Co\Gasco Sediments\Distributed Temperature Sensing Work Plan\0029-RP-001 VMAP.dwg FIG 1 Project Location Vancouver Portland Gresham Hood River OREGON Salem 0 2000 Scale in Feet NOTE: All locations are approximate. Figure 1 Site Vicinity Map Distributed Temperature Sensing Work Plan Gasco Sediments Cleanup Action
80 75 70 65 P:\Users\Rick Schwarz\Projects\GASCO\DTS Work Plan Temperature Graph.cdr Temperature ( F) 60 55 50 45 40 35 Groundwater Temperature Surface Water Temperature 30 Jan 2012 Apr 2012 Jul 2012 Oct 2012 Jan 2013 Apr 2013 Jul 2013 Oct 2013 Jan 2014 Date 19 May 2014 ejs Notes: 1. Surface water data from U.S. Geological Survey site monitoring site 14211720 at the Morrison Bridge, gage datum 1.55 above NGVD29. 2. Groundwater temperature minimum and maximum values from observations at wells P7-50, P7-100, and P7-150 between September 2013 and March 2014. Figure 2 Groundwater and Surface Water Temperatures Distributed Temperature Sensing Work Plan Gasco Sediments Cleanup Action
W I L L A M E T T E R I V E R F #* GCSEEP 7F 2 4 #* 6 GS-B7SM 1 3 5 7 Q:\Jobs\000029-02_Gasco\Maps\EECA\CostEstimates\Cable_line.mxd lhudson 6/12/2014 2:36:35 PM #* #* U.S. Moorings LWG Seepage Meter Location NW Natural Seepage Meter Location DTS Cable Layout (approximate) Interim Project Area Boundary Gasco Sediment Site Area of Interest (Final Work Plan [Anchor QEA 2009]) Federal Navigation Channel Fuel and Marine Marketing Lease Area NW Natural "Gasco" LNG Plant Siltronic Corp. NOTES: 1. Arrow indicates direction of flow of river. 2. Horizontal datum is NAD83 HARN Oregon State Plane North, Intl. Feet. 3. Vertical datum is NAVD88. 4. Aerial imagery from July 2007. 5. Distributed temperature sensing (DTS) uses differences in light transmission in a fiber optic cable to detect temperature differences associated with groundwater discharge. Feet[ 0 100 200 300 400 Figure 3 DTS Cable Layout Distributed Temperature Sensing Work Plan Gasco Sediments Cleanup Action