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Home My WebLink About047David W. Johnson From: Sent: To: Cc: Subject: Attachments: Barbara Moore-Lewis [brinnongroup@gmail.com] Thursday, November 19, 2009 6:29 PM David W. Johnson JimiCouture Brinnon Group comments on scoping process Comments to DCD for Scoping Process 11-30-09.pdf; waterworksConsultantsWaterReview. pdf; seawaterintrusion. pdf Attached are l) the letter from the Brinnon Group on the scoping process, 2) the report from Waterworks Consultants referred to in the letter, and 3) the seawater intrusion policy of Island County, referred to in the report. Please respond to this email to let me know you received everything. Thank you. Barbara Moore-Lewis 1 Brinnon Group Comments for Scoping Process November 30,2009 Emailcd to DCD November 30,2009 Thank you for the opporlunity to give input to the scoping process. The Brinnon Group is concemed about both tbe quality and the quantiry of water on Black Point. There seems to be no clear idea of the extent of the existing aquifer or the current or potential salt water intrusion. ln fact, it seems the development process has been backwards. Should we not first determine the resources available and base the development allowed on this data? Statesman has proposed a development that they deem to be financially viable. The developer has based its determination on potentially disastrous "snap shot" data" that the resources will support the development. They project their watcr usage to be 39 million gallons per year. How do we know tbe aquifer will support this? Their development plans include cutting and filling 2 million cubic yards of soil. What effect will this, along with drastically reducing the permeable surface area, altering the kettles, and removing mos! if not all, of the existing vegetation have on the hydrologic cycle? The answers to these and many other questions can only be obtained from anallzing cyclic data. We request that you implement the recommendations of Waterworks Consultants, which is attached. Below is a summary of these recommendations. Summary of Recommendations for Additional Testing To better understand the hydrogeologic response to the proposed water supply management scheme in this relatively sensifive poundwater environment, each of the components of the hydrologic cycle should be more accurately quantified. In addition, the aquifer properties must be better defined to design a supply system that does not overstress the aquifer, The following tests are recommended in order to gather that information. Aquifer properties Aquifer testing - pump tests should be conducted for a minimum of 72 hours in any wells that might be proposed for water supply purposes (American Campground Well, Pleasant Tides Coop lVell (Sam Boling lryater System/Black Point Water Company) and MW-2), Pump tests should be conducted for long enough to generate a measurable drawdown in at least two monitoring wells in the vicinity. Pumping rate at the Pleasant Tides Coop Well should include the 300 gpm for existing water rights plus the proposed new withdrawal. I Pump testing at MW-2 should include installation of a monitoring well, at a location tlrat is as close as existing wells are to the eastern shoreline, in I Brionon Group Comments for Scoping Process November 30, 2009 Emailed to DCD November 30, 2009 line with the MW-2 well, Chloride testing of water pumped from the aquifer should be done when the MW-z is pump tested. monitoring for water level drawdown and for chloride at the other Black Point Water Company wells, the Babare well, the Tudor well and the other Pleasant Harbor Beach Tract Owners wells. Seawaler tntrusion Chloride content in groundwater should be dstermhed in samples collected from wells purnped adjacent to the marine shoreline over the duration of the pump tcsts. At a minimum one samplc should be collected prior to initiation of pumping, another after at least l2 hours of pumping and a third shortly before pumping is stopped. More samples provide more confidence in the data collected, and the interpretations derived from that data. Chloride concentrations between 100 and 200 mg/I indicate wells at moderate risk for seawater intnrsion, with 200 rng/l being the trigger for high risk, according to Island County's Seawater lntrusion Policy (a copy is included with these cornments as an Attachment ). Groundwater nnvetnent Groundwater levels should be measured in every accessible well on the same date, so that a groundwater elevation contour level map can be constructed that is reliable for interpreting ttre direction(s) of groundwater movement. A better understanding of the direction of groundwater movement will support a better interpretation of the groundwater withdrawal impacts to privatc wells on the Black Point Peninsula and seawater intrusion risk. Water Budget The presentation of the water budget in the Report makes it impossible to assess the individual cornponents of the water budget, their relationship to each other, and what data was used to derive them. A comprehensive explanation of the water balance calculations must be provided. This should include: 2 Brinnon Group Comments for Scoping Process November 30, 2009 Emailed to DCD November 30,2009 In particular the following components need better delineation. Precipilation Precipitation should be monitored on the Black Point Peninsula site for the duration of a year (concurrent with other monitoring data collection). Recharge Groundwater levels should be monitored with continuous eleckonic logs in the three monitoring wells, and reported for the duration of a year to assess the range of groundwater level variation, and the recharge resulting from precipitation events. Precipitation monitoring should coincide with groundwater level monitoring periods. Precipitation should be used to evaluate the changes in groundwater levels associated with precipitation events (i.e. recharge) Evapotran.spiration Evapotranspiration calculations, and the data and assumptions used in those calculations needs to be presented in report form. Streamtlou, Stream flow emitting from the lake on the eastern margin of the Peninsula, and flowing to the east shoreline should be monitored to assess the rate of surface water runoff frorn the Peninsula. Lake Level Monitor lake (located in the central-eastern portion of BlackPoint Peninsula) level elevation over the period of a year concurrent witb other monitoring data collected. The Brinnon Group is also concerned that previous environmental impact analyses of traffic are incomplete and misleading. Collisions with animals and motorcycle accidents, both of which can [:e fatal, do not seem to be included. Only traffic accidents at intersections are included. Many accidents, some of them fatal, have taken place in recent years orl l0 i in places other than intersecfions. We would like to see complete numbers of acciderrts reflected in the SEIS. We would also Iike to see an analysis of the period of time that the liood Canal Bridge was closed and the impact on the rate of accidents and other traffic data, such as traffic congestion. 3 Brinnon Group Comments for Scoping Process November 30, 2009 Emailed to DCD November 30,2009 ln addition, there needs to be an analysis of the impact of an estimated 3400 kuck loads of soil being rernoved and the additional logging trucks that will be used to strip the current trees from the site. The Brinnon Group is concerned that Statesman will negotiate shoreline buffers that are not compatible with those being adopted by the Jefferson County Commissioners. Many citizens have given input on preserving our shoreline and moving to 150 foot buffers. This is particularly important along the Hood Canal. Will the development agreement negate our best scientific knowledge about how to protect our habitat and water quality in Hood Canal? What are the buffers that are proposed for the new development. If they do not meet the county's shoreline management program, what are the reasons? What will be done for mitigation? Is rnitigation appropriate? The Brinnon Group urges the county to enforce thc adopted shoreline buffer rules and not to give any variances to this large and potentially damaging development. The Brinnon Group is concemed about the discharge of nitrates from the proposed golf course. How will Statesnran ensure that the drinking water and Hood Canal water standards are lnet? Sincerely, J Couture President, Brinnon Group 4 Re Waterworks Consu ltants 4017 Willowbrook Lane Bellingham, WA 98229 360-296-8084 Memo To: Gerald Steel From: Llyn Doremus Date: July 17,2009 Technical review of: Water Supply and Groundwater lmpact Analysis Pleasant Harbor Marina and Golf Resort - November 20,2008 (SDEIS) Recommendations for Additional Hydrogeologic Testing at Black Point Background The Pleasant Harbor Marina and Golf Resort is planned for construction on the Black Point Peninsula in Hood Canal. The peninsula is surrounded by salt water for more thanT5o/o of it's shoreline. At least 15 wells are located along the Black Point eastern and northern shorelines that are at risk of seawater intrusion. Hood Canal is known to have a serious problem with depleted dissolved oxygen content, which has resulted in what has been termed a "dead zone". The dead zone creates conditions where a wide range of sea life that requires dissolved oxygen in the waters of their environment cannot survive. The depleted oxygen condition is known to result from enhanced activity of bacteria and algae that is promoted by discharge of nutrients (nitrogen and phosphorus) dissolved in surface and groundwater to Hood Canal. The two conditions: seawater surrounding the Black Point Peninsula and the potential for seawater intrusion to degrade water quality in shoreline wells, and extreme sensitivity of Hood Canal biologic health to the release of nutrients generate a very delicately balanced hydrogeologic environment in which the Resort is proposed for construction. The Resort water supply for residential, commercial and irrigation purposes has been proposed through a combination of rainwater capture, reuse, reclamation, infiltration, and groundwater withdrawal processes. While the general scheme of the suppty system has been outlined in previous documents, the specifics of how each of the components will operate has not yet been accurately defined. The potential for negative impacts of the various supply system components on the delicately balanced hydrogeologic environment is high. A sophisticated understanding of the Black Point hydrogeologic system is mandated to assess potential for degradation from the proposed water supply scheme to dissolved oxygen levels in Hood Canal, to seawater intrusion into the Black Point aquifer, and for the design, maintenance and operation of that system to function without degrading the Black Point aquifer and Hood Canal. These comments address the hydrogeologic characterization presented in the report: Water Supply and Groundwater lmpact Analysis, Pleasant Harbor Marina and Golf Resorf by Subsurface Group, LLC. November 20,2008 (Report) with respect to the information necessary for characterization, design and operation of a water supply system that does not degrade the Black Point aquifer. The accuracy and completeness of the Report assumptions, information and conclusions are assessed, and recommendations for additional testing to fill in the information gaps in the Report are listed. RECOMMENDATION FOR ADDITIONAL TESTING The Report describes results from a pump test conducted in the American Campground well ior 48 hours to assess the permeability and other aquifer properties in the well vicinity. The data generated by the test was found to be insufficient to assess the aquifer properties, because the drawdown in Water Supply and Groundwater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 2 Hydrogeologic System Groundwater moves through the sediments and rock, which, along with the other water moving through the system, defines the hydrolgeologic system of a specific site. Sediment tends to form in layers, which can be visualized as a "layer cake" type configuration. Sediments and rock layers with a large percentage of void spaces typically transmit water more quickly, which is termed a high permeability hydrogeologic unit. Sediment layers that are more dense, with tiny void spaces are termed "low permeability" or "impermeable". Low permeability sediment layers impede downward migration (infiltration) of groundwater, and tend to accumulate water on their upper surface. This is normally how unconfined aquifers form. The permeability of an aquifer is usually determined by conducting a pump test. With the exception of the single pump test of the American Campground well, and the marginal data generated from that test, there is no data presented on the aquifer properties of the various hydrogeologic units on the Black Point Peninsula. the monitoring wells was almost undetectable. Pump testing should be conducted in all of the wells that are proposed for water supply purposes. The pumping rate used should be equivalent to the rate at which water is proposed for withdrawal for the water supply needs of the resort (at a minimum 75 gallons per minute to provide the 121 acre feet annual use projection), because of the likelihood that individual wells may be relied upon for the full volume for the resort water demand when problems with water level drawdown and seawater intrusion occur. The tests should be run for sufficient duration (minimum 72 hours) to derive measurable drawdown curve in at least one of the monitoring wells, so that reliable aquifer properties can be calculated. The direction of groundwater movement is defined by the groundwater gradient. Groundwater moves from locations of high water elevation level to low elevation discharging eventually to lower-elevation surface water bodies. The groundwater elevation pattern often mimics the ground surface topographic elevation pattern. Downgradient (lower groundwater elevation) locations manifest the affects of groundwater movement and withdrawal in hlgher elevation locations. lt is important to understand the directions of groundwater movement in order to assess the magnitude and distribution of ground water level decreases associated with groundwaterwithdrawal (pumping from wells). ln particular, reduction in the groundwater levels in shoreline areas increases the risk of seawater intrusion into water supply wells. The Report presents an interpretation of groundwater flow direction towards the center of the peninsula and then to the east (discharging into Hood Canal). The groundwater surface elevation contours are illustrated in Figure 4 of the Report, and suggest that a groundwater high point (at MW-2) dominates groundwater flow direction on the entire peninsula. That single data point (MW-2 water level elevation) is disproportionally valued in interpreting the groundwater flow directions. RECOM M ENDATION FOR ADDITIONAL TESTING Groundwater levels should be measured in every accessible Black Point Peninsula well on the same date, so that a groundwater elevation contour level map can be constructed that is reliable for use in interpreting the direction(s) of groundwater movement. A better understanding of the direction of groundwater movement will support a better interpretation of the groundwater withdrawal impacts to private wells on the Black Point Peninsula and seawater intrusion risk. Water Supply and Groundvrater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 3 Diagrams of the Black Point Peninsula hydrogeologic system are presented in the Report Figures 11 , 12 and 13. Much of the site is covered with dense, low permeability till. About one third of the site has additional sediments deposited on top of the till that are higher in permeability and allow water to migrate more quickly through them. Water that migrates downward through these higher permeability sediments might slow down and accumulate in a "perched" aquifer upon encountering the underlying low-permeability till. There is no evidence of perched conditions at this site presented in the Report. Basalt bedrock is shown in Figures 13 in wells located on the northern part of the site. The contribution of groundwater flow transmitted through bedrock to the Black Point aquifer is not well characterized in the Report, nor is the bedrock permeability, or the hydraulic connection between bedrock and the overlying unconsolidated sediments. With the exception of the single pump test of the American Campground well, and the marginal data generated from that test, there is no data presented on the aquifer properties of the bedrock or unconsolidated sediment hydrogeologic units on the Black Point Peninsula, or on the hydraulic continuity between unconsolidated sediment units and the bedrock underlying them. Further pump testing (as previously described) is necessary to better define aquifer properties of the hydrogeologic units and the hydraulic continuity with bedrock on the site. Water Budget A water budget uses estimates or measurements of each component of the hydrologic cycle to assess the entire movement of water through a speciflc hydrologic system annually. For the purposes of characterizing the impact of the proposed water management scheme on the the Black Point Peninsula aquifer and hydrogeology, the water budget should encompass the entire Peninsula. To prevent or at least minimize detrimentalimpacts it is essential that the components of the water budget are defined as accurately as possible. A typical equation for a water balance is as follows. Ppt=E+Q+dSn+69 Where: Ppt = annual precipitation E = annual evaporation plus transpiration (evapotranspiration) Q = stream flow or surface water runoff dS. = the change in quantity that is stored as surface water for the year (negative for a decrease in the water quantity in surface storage) Water Supply and Groundwater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 4 dSs = the change in the water quantity that is stored as groundwater for the year (negative for a decrease in the groundwater storage, indicating a drop in groundwater levels) Surface Water Flow Although surface water is not flowing onto the proposed Pleasant Harbor Resort site, the quantity of water discharged from Black Point Peninsula as stream flow impacts the water budget for the Peninsula. Accurate stream flow measurements help reduce uncertainty in other portions of the hydrologic budget that are more difficult to estimate. Stream flow emitting from the lake in the eastem-central portion of Black Point Peninsula, as well as any other stream flow on the Peninsula needs accurate assessment in order to calculate its contribution to the water budget, and its influence on the other components of the budget. RECOMMENDATION FOR ADDITIONAL TESTING (Q) Stream flow emitting from the lake on the easterncentral margin of the Peninsula, and flowing to the east shoreline should be monitored to assess the rate of surface water runoff from the Peninsula. Surface Water Sforage Surface water is typically stored in lakes and wetlands. To better understand the changes in surface water storage that are ongoing under current conditions (dSs), and that may be expected from the proposed use of kettles as water storage facilities, the water sbred in Lake (on the eastern margin of the Peninsula) should be monitored for changes in lake elevation. lt is likely that the lake is in hydraulic continuity with groundwater, and receives groundwater discharge. A better delineation of lake level variations, and their relationship to precipitation quantities and timing, and groundwater levels will improve the understanding of how groundwater moves through the Peninsula hydrogeologic system. RECOMMENDATION FOR ADDITIONAL TESTING (dSs) Monitor lake level elevation over the period of a year (concurrent with other monitoring data collected). Precipitation Precipitation provides water that supports the various water uses and hydrologic components. Annual precipitation at this site is poorly understood because of the variability in precipitation along the north south extent of Hood Canal, and the lack of monitored data collected in the Black Point Peninsula or Brinnon vicinity. Water Supply and Groundwater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 5 RECOMMENDATION FOR ADDITIONAL TESTING (Ppt) Precipitation should be monitored on the Black Point Peninsula for an entire year. ln addition, the data available from the NOAA approved weather station at location A5461 on the west side of Hwy. 101 across from Pleasant Harbor should be analyzed. See Attachment t hereto. Groundwater Storage Groundwater that is stored in an aquifer is the amount of water that is added to the aquifer over the course of the year (termed recharge) minus the amount withdrawn or discharged from the aquifer. Recharge to an aquifer derives from precipitation that infiltrates into the ground. Discharge from an aquifer typically goes to stream flow (Q), or it may be pumped for water supply or irrigation purposes, or, in this case, includes flow into Hood Canal to diminish salt water intrusion into the fresh water supply. The difference between the amount recharged and the amount discharged is the change in storage (dsg). Quantification of recharge is an important factor in assessing the storage changes in groundwater, as is quantification of the discharge. Recharge of an aquifer results from vertical infiltration of precipitation that falls on the ground surface overlying the aquifer. Aquifers are more rapidly recharged when the sediment overlying the aquifer is of "high permeability" and when there is high annual precipitation. Consider if the precipitation that infiltrates to recharge the aquifer is half (50%), the standard assumption when data is not available to calculate actual recharge rates. For this site the annual precipitation rate is not well known, which makes the annual recharge rate even more difficult to assess. Table 3 lists 55 inches for annual precipitation in Quilcene (the closest site monitored). Half of this is 27 inches, or 2.3 feet. For this 220 acre site, this provides an annual recharge of 504 acre feet (significantly less than the 783 acre feet claimed in the Report on page 17). The presence of low permeability till will slow down groundwater infiltration, and likely reduce the rate of groundwater recharge to the aquifer even further than estimated using these assumptions. There will be substantial additional evapotranspiration caused by the watering of the golf course and other vegetation in the hot months of the year. This has not been adequately considered. RECOMMENDATION FOR ADDITIONAL TESTING (dsd) Groundwater levels in the three monitoring wells (MW-1, MW-2 and MW-3) should be monitored for at least one year, to determine the variation in groundwater elevation. Precipitation should be monitored on the site for at Water Supply and Groundwater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 6 least one year to determine the actual precipitation received annually (concurrently with other monitoring data collected). Analyses of recharge quantities and rates should be done using monitored data, and presented in the calculation of the water budget for the site. A separate set of calculations should be done assuming serious drought conditions - perhaps an estimated 500-year drought. Quantification of groundwater discharge is calculated using measurements of changes in groundwater elevation, stream flcnv measurements, pumped quantities from the aquifer, and precipitation measurements. lt is important to delineate the groundwater flow direction and to delineate locations of groundwater discharge, to more accurately assess the annual amount of groundwater discharging from the aquifer. The change in groundwater storage calculated amount (dsg) relies upon an accurate estimation of annual groundwater discharge and its relative value with respect to the annual recharge amount. Additionally, discharge of groundwater from beneath the proposed resort to Hood Canal, that contains contaminated landscaping chemicals (especially nitrate and phosphorus) poses a significant risk to the environmental health of Hood Canal. Evapotranspiration The information presented in the Report on estimations of evapotranspiration (24.1 or 24.2 inches per year), need to be presented with data, formulas, tables, and assumptions used in those calculations, as part of the comprehensive water budget estimation. Summary of Recommendations for Additional Testing To better understand the hydrogeologic response to the proposed water supply management scheme in this relatively sensitive groundwater environment, each of the components of the hydrologic cycle should be more accurately quantified. ln addition, the aquifer properties must be better defined to design a supply system that does not overstress the aquifer. The following tests are recommended in order to gather that information. Aquifer propefties Aquifer testing - pump tests should be conducted for a minimum of 72 hours in any wells that might be proposed for water supply purposes (American Campground Well, Pleasant Tides Coop Well (Sam Boling Water System/Black Point Water Company) and MW-2). Pump tests should be conducted for long Water Supply and Grounduater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 7 enough to generate a measurable drawdown in at least two monitoring wells in the vicinity. Pumping rate at the Pleasant Tides Coop Well should include the 300 gpm for existing water rights plus the proposed new withdrawal. . Pump testing at MW-2 should include installation of a monitoring well, at a location that is as close as existing wells are to the eastern shoreline, in line with the MW-2 well. Chloride testing of water pumped from the aquifer should be done when the MW-2 is pump tested. o Pump testing at the Pleasant Times Coop Well should include monitoring for water level drawdown and for chloride at the other Black Point Water Company wells, the Babare well, the Tudor well and the other Pleasant Harbor Beach Tract Owners wells. Seawater intusion Chloride content in groundwater should be determined in samples collected from wells pumped adjacent to the marine shoreline over the duration of the pump tests. At a minimum one sample should be collected prior to initiation of pumping, another after at least 12 hours of pumping and a third shortly before pumping is stopped. More samples provide more confidence in the data collected, and the interpretations derived from that data. Chloride concentrations between 100 and 200 mg/l indicate wells at moderate risk for seawater intrusion, with 200 mg/l being the trigger for high risk, according to lsland County's Seawater lntrusion Policy (a copy is included with these comments as Attachment 2). Groundwater movement Groundwater levels should be measured in every accessible well on the same date, so that a groundwater elevation contour level map can be constructed that is reliable for interpreting the direction(s) of groundwater movement. A better understanding of the direction of groundwater movement will support a better interpretation of the groundwater withdrawal impacts to private wells on the Black Point Peninsula and seawater intrusion risk. Water Budget The presentation of the water budget in the Report makes it impossible to assess the individual components of the water budget, their relationship to each other, and what data was used to derive them. A comprehensive explanation of the water balance calculations must be provided. This should include: . water budget equation used . Values for each component the equation Water Supply and Groundwater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations 8 . data, calculations and assumptions used to derive each value ln particular the following components need better delineation. Precipitation Precipitation should be monitored on the Black Point Peninsula site for the duration of a year (concurrent with other monitoring data collection). Recharge Groundwater levels should be monitored with continuous electronic logs in the three monitoring wells, and reported for the duration of a year to assess the range of groundwater level variation, and the recharge resulting from precipitation events. Precipitation monitoring should coincide with groundwater level monitoring periods. Precipitation should be used to evaluate the changes in groundwater levels associated with precipitation events (i.e. recharge) Evapotranspiration Evapotranspiration calculations, and the data and assumptions used in those calculations needs to be presented in report form. Streamflow Stream flow emitting from the lake on the eastern margin of the Peninsula, and flowing to the east shoreline should be monitored to assess the rate of surface water runoff from the Peninsula. Lake Level Monitor lake (located in the central-eastern portion of Black Point Peninsula) level elevation over the period of a year concurrent with other monitoring data collected. Water Supply and Grounduater lmpact Analysis, Pleasant Harbor Marina and Golf Resort Technical Review and Recommendations I I 2 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3l)S,Approved by BOCC 3/'16/05 Island County / WRIA 6 Watershed Planning Process capable of supplying water to wells (aquifers). These aquifers are interbedded with lower permeability layers of silt and clay (aquitards) that pass water more slowly. Aquifers and aquitards in Island County vary spatially in both thickness and elevation, Figure 4. In any given area of the county, there may be several aquifers present, and each aquifer willhave different hydraulic characteristics (recharge, pressure, capacity etc) and susceptibility to seawater intrusion. Even within a single aquifer, the hydraulic characteristics can vary significantly from one location to another. It is this variability and complexity of our groundwater system that makes the question of 'How much water is there?' so difficult to answer. As a result, water resource Figure 4 planning and management efforts have primarily relied on review of water use proposals on an individual basis. The scope and detail of the project review has relied on a triggering mechanism known as the Island County Saltwater Intrusion Policy. 2.0 Current Saltwater Intrusion Policy In 1989 the Island County Health Department, in conjunction with the Washington State Department of Health, adopted the Island County Saltwater Intrusion Policy. The primary function of the policy is to trigger additional review (of potential for seawater intrusion) of new or expanding public water systems in areas where seawater intrusion appears to be occurring. The goal of this policy is to protect public water supplies from seawater intrusion. 37 29 30 3l 32 JJ 34 35 36 38 39 40 4l 42 43 44 45 46 48 49 50 5l 52 53 54 55 56 57 58 The policy utilizes chloride concentrations in wells as its indicator of seawater intrusion and defines 'risk zones', drawing t/z mile circles around wells with elevated chloride concentrations. An area where all wells within % mile have chloride concentrations less than I00 milligrams per liter (mg/l) is considered 'low risk'. An area where one or more wells have chlorides between 100 lslard Curnll Sem,ater Intrusion Polic]' Circlc Map ,l i t .' s*&e 5 47 and 200 mg/l is considered 'medium risk', and an area with one or more wells with chloride concentrations greater than 200 mg/l is considered 'high risk'. Drawing %mile circles around wells with elevated chloride concentrations yields the map shown in Figure 5 known as the Circle Map. Inspection of Figure 5 shows a pattern where the majority of the % mile circles fall along the shoreline, which makes sense in light of the conceptual model shown in Figure 2 with the freshwater C:\ My Documents\Word\WatershedPlanning\Seawater IDtrusion (Final).doc aJ. Editor: Doug Kelly I 2 J 4 5 6 7 8 9 l0 ll l2 l3 14 l5 t6 17 l8 t9 20 2l 22 23 24 25 26 27 28 29 30 3l 32 JJ 34 35 36 37 38 39 40 4l 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/05, Approved by BOCC 3/1,6/05 Island County / !7RIA 6 Watershed Planning Process lens having a maximum thickness near the center of the island, thinning approaching the shorelines. However there are exceptions to this pattern, where isolated circles, and even clusters of circles fall away from the shorelines toward the island interiors. This discrepancy suggests a problem, either in the conceptual model of groundwater flow and seawater intrusion in an island environment, or with the use of chloride concentrations as the indicator of seawater intrusion. 2.1 Limitations of the Current Saltwater Intrusion Policy Over ten years of experience in the application of the Saltwater Intrusion Policy has shed light on some limitations of the policy. The first limitation is the fact that there are other sources of chloride in the environment other than seawater intrusion. Non-intrusion chloride sources include: connate (very-old) groundwater, septic system effluent, very hard groundwater, windblown sea spray, and recharge from irrigation, agricultural practices, and well disinfection. Chloride from any of these sources can result in elevated levels of chloride concentrations in an aquifer, triggering the Saltwater Intrusion Policy when in fact the aquifer is not intruded. This erroneous interpretation of data is known as a false positive, where a test identifies a problem that does not in fact exist. Figure 6 displays a chloride circle map for a portion of Central Whidbey Island. Although some of the circles bordering the shoreline on the map probably represent elevated chlorides due to seawater intrusion, it is believed that the majority of the inland circles are caused by something other than seawater intrusion; in this part of Whidbey Island, very hard groundwater appears to be to the source. Various chemical analysis tools have been utilized in an attempt to differentiate between chlorides caused by seawater intrusion and other sources, however no tool has been found that can differentiate all of these sources. In some cases, such as windblown sea spray, an aquifer may be impacted by seawater that is entering the aquifer from above. Chemically this may be indistinguishable from seawater entering laterally, but this movement of seawater into the aquifer has nothing to do with over-drafting the aquifer and classical seawater intrusion. The ambiguity of chloride source can result in incorrectly classifoing a proposal as having risk for seawater intrusion, potentially costing significant time and financial costs for both the applicants and the permitting agencies. Denial of applications based on apparent risk for intrusion that is non-existent is also possible. False positives are one potential problem for the Saltwater Intrusion Policy; a second involves the opposite effect, a false negative. False negatives occur when a test indicates that a problem does not exist, when in fact it does. In the overview of groundwater and seawater intrusion presented earlier in this paper, the mechanisms that influence the location and movement of the saltwater interface were discussed. The processes of groundwater recharge, flow, mixing, and discharge all combine to hold the interface position in a roughly stationary position. A change to any of these processes will C:\My Documents\Word\WatershedPlmning\Seawater Intrusion (Final).doc 4. Circle MapCentral Editor: Doug Kelly 012345 xlm 1 2 J 4 5 6 7 8 9 10 l1 12 13 t4 l5 l6 t7 18 l9 20 21 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 37 38 39 40 4t 42 43 44 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by !7RAC: 2/3/}S,Approved by BOCC 3/16/05 Island County / \fRIA 6 Watershed Planning Process result in a change in the position of the interface. However, the change in interface position following a change to the flow regime is not instantaneous, but instead the interface can take a significant amount of time to come into a new equilibrium position. One of the principal tools used in evaluating proposed groundwater withdrawals is an aquifer test, where a well is pumped for a period of time and the aquifer's response (drawdown) to this pumping is monitored. Analysis of how an aquifer responds to pumping yields numeric values that quantiff the hydraulic characteristics of the aquifer, primarily hydraulic transmissivity and storativity. These aquifer parameters can then be utilized to estimate how the aquifer will respond to pumping over longer periods of time. In areas where seawater intrusion is a concern, water samples are typically collected during the test and sent to a laboratory for analysis of substances related to seawater intrusion. Since most of the 'other sources' of chlorides tend to be persistent, significant rises in chloride concentration during an aquifer test can generally be attributed to seawater intrusion. If no variation in chloride concentration occurs during a test, it is tempting to assume that seawater intrusion is not, and will not become a problem. However, a lack of change in chemistry during an aquifer test does not prove that intrusion (caused by the proposed withdrawal) will not occur at some later time. It is quite possible that the interface was at some distance from the well at the beginning of the test, and moved toward the well during the test, but did not reach the well screen, and as a result no change in chemistry was detected. Once the well is put into fulltime use, the interface may continue to move inland resulting in seawater intrusion. Using chemistry as a tool to evaluate risk for seawater intrusion may show intrusion is occurring (excluding the problems with false positives discussed previously), but it cannot evaluate if intrusion is Iikely to occur in the future. In essence, chemistry is a not a predictive tool - it cannot predict that intrusion willoccur in the future. Instead, chemistry is a reactive tool, capable only of reacting to intrusion once it begins to occur, and in some cases too late to prevent significant degradation of groundwater quality. The use of a reactive rather than a predictive test for intrusion risk results in a lack of confidence in the water resource. Areas of the circle map that are currently ranked as low risk (no circles) have no information beyond the fact that intrusion has not occurred to date. This map gives no indication of whether or not there is either an ample supply of water or if intrusion is about to begin. This leaves the public and water resource managers in a state of constant uncertainty. Ultimately we need a tool that can assess the adequacy ofour aquifers, and differentiate between those aquifers that have ample fresh water quantity and those that are only marginal. 3.0 Water Level Elevations and Seawater Intrusion Earlier in this paper, the factors that influence the position and movement of the saltwater interface within an aquifer were discussed. Primary among those factors is the pressure in the freshwater zone relative to sea level, known as the Ghyben-Herzberg Relation. In order to prevent seawater from entering a freshwater aquifer, adequate freshwater pressure must be maintained. An aquifer's C:\My Documents\Word\WatershedPlanning\Seawater Intrusion (Fina.l).doc 5. Editor: Doug Kelly I 2 J 4 5 6 7 8 I l0 ll l2 l3 t4 l5 16 t7 l8 l9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 )t 38 39 40 4l 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/}S,Approved by BOCC 3/16/05 Island County / WRIA 6 Watershed Planning Process susceptibility for seawater intrusion can be evaluated by measuring the distribution of water level elevations. Thus the relationship between an aquifer's water level elevation and its susceptibility to seawater intrusion can be utilized as a planning and resource management tool. If employed in the same manner as the current Seawater Intrusion Policy, as a method of flagging a proposal for more detailed review, it may overcome virtually all of the policy's current limitations. An aquifer that has water level elevations (pressure) significantly above sea level is not at risk for seawater intrusion, while an aquifer that has near sea level water levels is at risk. A more sophisticated analysis would be required to answer the question of whether or not the low-pressure aquifer would actually intrude due to a proposed withdrawal, but the risk for intrusion is definitely present. If aquifer water level elevations can be accurately determined, incorrectly identifoing an area as being at risk for intrusion (false positives) should not occur. The abilify to accurately predict whether or not a proposed withdrawal will induce seawater intrusion into an aquifer varies with the complexity of the aquifer system, and how well the aquifer system is understood. However, predicting the long-term impact of a proposed withdrawal on the water level elevations in an aquifer is relatively simple, and thus it would be unlikely that a proposal would be ranked as having no risk of intrusion (false negative) where risk actually exists. Thus using aquifer water level elevations coupled with aquifer testing and some type of drawdown calculations provides a predictive tool for evaluating risk for future intrusion. Finally, in areas where aquifers have substantial pressure above sea level, the public and water resource managers can be assured that unless this pressure is reduced, the aquifers are not at risk for intrusion. Similarly if an aquifer does not have significant pressure, but intrusion has not yet occurred, planning and management tools can be employed to help alleviate problems before they occur. 4.0 Phase II Assessment The primary goal of the Watershed Planning Phase II Assessment is to quantiff the water resources within a water resource inventory area (WRIA). For many WRIAs the primary resource is a river system, and quantification of the resource is relatively straightforward, involving collection of flow data from that system. In WRIA 6 (lsland County) our primary water resource is contained in multiple discontinuous aquifers, with variable connection to recharge areas and the saline waters of the Puget Sound. The complexity of our groundwater system makes it virtually impossible to accurately quantifr of the resource as a whole. As a result, the WRIA 6 planning unit opted to make the primary focus of its Phase II Assessment the evaluation of risk for seawater intrusion, utilizing water level elevations as the assessment tool. In order to determine the water level elevation in an aquifer, two measurements are required. First a depth to water measurement is taken, finding the distance between the measuring point (typically the top of the well casing) and the water level. In order to convert this depth to water measurement into an elevation, the elevation of the measuring point must be determined. The depth to water is then subtracted from the measuring point elevation to find the water level elevation. C:\My Documents\Word\WatershedPlanning\Seawater Intrusion @inal).doc 6. Editor: Doug Kelly I 2 3 4 5 6 7 8 9 l0 l1 t2 l3 t4 l5 16 t7 18 l9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 JI 38 39 40 4t 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/05, Approved by BOCC 3/1.6/05 Island County / WRIA 6 Watershed Planrung Process Determination of the elevation of the measuring point has traditionally been accomplished through the use of a differential level loop survey from the nearest vertical benchmark(s) to the well. Although traditional surveying can provide accurate elevation data, in many cases the time and costs associated with this method make it impractical. Recent advances in survey-grade GPS (Global Positioning System) technology have resulted in devices that are capable of determining the elevation of a location in a fraction of the time required for traditional surveying methods. I +.t Phase II Data Collection In order to evaluate the effectiveness of water level elevation as a tool for assessing seawater intrusion risk, water level elevation data from both intruded and non-intruded areas of the county was needed. To fulfill this need, data was collected from nearly 400 wells across the county, or roughly two wells per square mile. For each well utilized in the study, depth to water measurements were collected, and where possible a computerized data logger was installed in the wells to evaluate water level variations over time. In addition a water sample was collected from each well, and sent to a state-certified laboratory for major ion analysis. Through a grant provided by the Washington State Department of Ecology, Island County was able to purchase a global positioning system (GPS) consisting of three survey-grade receivers and associated hardware. Two of these receivers were set up as perrnanent base stations to provide post- processing data, and the third was utilized as a roving unit to collect measuring point elevation data from each well utilized in the study. Volunteers willing to let the county collect data from private and public water system wells were solicited via newspaper articles and direct mailings. In selecting wells for use in the study, we attempted to achieve an even distribution spatially at approximately two wells per square mile. Since we hoped to measure static (non-pumping) water levels, preference was given to wells with fewer homes connected. Preference was also given to wells completed (screened) below sea level. In any given area, if more than one aquifer was present, we attempted to collect data from the two most frequently utilized below sea levelaquifers. Over 730 wells were volunteered, of which field crews visited more than 470. Not all wells that were visited by our field crews could be utilized in our study. Wells that did not have access for measuring depth to water, or wells that did not have the ability to provide an untreated water sample were dropped from our study, resulting in a total of 379 wells from which all necessary data was successfully collected. Water level and chemistry data was collected from the study wells during the summers of 2001 and 2002; surveying of measuring point elevations was conducted from the spring of 2003 through the spring of 2004. Aquifers can be influenced by tidal fluctuations in adjoining marine waters, resulting in variations in both water level and chemistry. Generally, wells that are affected by seawater intrusion and that are tidally influenced tend to exhibit higher chloride concentrations and water levels during higher tides. In an attempt to collect consistent data, wells that fell within % mile of the marine shoreline were monitored (water sampling and depth to water measurements) during a *6 foot or higher tide stage. C:\My Docments\Word\WatershedPlanrung\Seawater Intrusion (Final).doc 7. Editor: Doug Kelly I 2 3 4 5 6 7 8 9 l0 ll t2 l3 t4 SEAWATER INTRUSION TOPIC PAPER (Final) i:,lTJtiJ"Hff {i':'#',:,','J.Ti#""rT;#iJ:' I l.Z Phase II Data Analysis The primary goals of the Phase II Assessment were to evaluate the use of water level elevation data as a tool for determining seawater intrusion risk, and to provide water level elevation data on a countywide basis to provide a new view of intrusion susceptibility. Evaluation of water level elevation data as a seawater intrusion tool can be approached in several ways. One method involves comparing intrusion (or lack thereof) from the perspective of water chemistry to the water level elevation data. As discussed earlier, there are several problems associated with the use of chemistry for evaluation of seawater intrusion. These problems complicate the use of chemistry as a tool for validation of the water level elevation methodology for seawater intrusion analysis. Several different methods were utilized in our analysis of the chemistry data. The most simple of these methods was simply comparing chloride concentrations to water level elevations as shown in Figure 7. One problem with this analysis is the significant number of 'false positives' where there o o Central Whidbey o Other Wells3o o 0 a t ( oob^ o 916 a .On6 400 600 800 Chloride (mg/l) Figure 7. are elevated chlorides that are not due to seawater intrusion. One area of known false positives for chloride data is Central Whidbey Island. These wells are impacted by very hard groundwater, which results in elevated chloride concentrations that do not appear to be caused by conventional seawater intrusion. Figure 7 differentiates the wells in Central Whidbey from all other wells as shown in the legend. With the exception of the data from Central Whidbey, the plot displays the expected results, with elevated chloride concentrations occurring with lower water level elevations. Another type of analysis that has application to seawater intrusion is a piper diagram, where chemical sample results are plotted based on the relative proportion major ions (Figure 8). For each water sample, a point is plotted in the lower left triangle based on the proportions of positively charged ions (cations), and a second point is plotted in the lower right triangle based on the proportions of negatively charged ions (anions). These two points are then extrapolated up into the upper diamond to place a third point. C:\My Documents\Word\WatershedPlanning\Seawater Intssion (Final).doc 8. 400 300 200 100 rc.l! olrJ o_o fisJA gs 0 2000 I 000 1200 1400 1 600 l5 l6 t7 l8 l9 20 2l 22 23 24 25 26 27 Editor: Doug Kelly ...........). - -.. - ----i --- S** &,s" SEAWATER INTRUSION TOPIC PAPER (Final) Approved by !7RAC: 2/3/}s,Approved by BOCC 3/1,6/05 Island County / WRIA 6 Watershed Planning Process I 2 3 4 5 6 7 8 9 10 ll t2 l3 t4 l5 l6 t7 l8 t9 20 2l 22 23 In general, fresh groundwater samples will land near the area labeled as 'fresh' in the upper diamond, while pure seawater will plot near the 'sea' label. Water that results from conservative mixing (mixing without ionic exchange reactions) between freshwater and seawater would plot along the line labeled 'mixing'. When mixing occurs in the presence of aquifer materials, ion exchange reactions often occur between the groundwater and the aquifer material, which alter the chemical composition of the water. This change in chemical composition results in a deviation from the conservative mixing line on the piper diagram, moving the point upward into the upper portion of the diamond during intrusion, and downward toward the lower portion of the diamond during freshening. Using this method, it Fresh Slight Intrusion Intrusion Slight Conserlntive C'onseltirtive l\Iixing Slight Freshening F reshening 80 a0 a0 20 - Celctm Cations Fisru'e 9 Editor: Doug Kelly &80{a ,!40E Figurc 8 is possible to deduce not only if a water sample is impacted by intrusion, but also if the intrusion was getting worse (intrusion exchange) or better (freshening exchange) at the time the sample was taken. Figure 9 is a piper diagram plotting the chemistry data from all of the wells utilized in the Phase 2 assessment. The color of the each data point in the upper diamond reflects the elevation of the bottom of the well as shown in the legend. The radius of each upper diamond data point reflects the total dissolved solids (TDS) for that sample, with larger circles having greater quantities of dissolved minerals. A program was developed that automatically evaluates the sample results, assigning each sample a code indicating where it lands on the diagram as shown in Figure 9. The samples collected as part of the Phase II Assessment were processed using the above methodology to evaluate the ion balance ofeach, and then these results were grouped and the average water level elevation (in feet above MSL) for each grouping was evaluated. Scleenerl Elevrtion is: O Ahove Sea Level 1> +30') Neirr Sear Leyel (+/- J0') O Belorv Sea Lrvel (< -30') /-'l000opomf /soooo}m \/ Tdd Dissdved Sdids (parts per millim) 60 & Anions C:\My Documents\Word\WatershedPlmning\Seawater Intrusion (Final).doc 9. .@ Gl':rrling (lriterin SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/}S,Approved by BOCC 3/16/05 Island County / WRIA 6 Watershed Planning Process The results of this evaluation are presented in Table l. This analysis was performed on data that excluded wells that are completed above sea level and those wells in Central Whidbey where anomalous chemistry is known to occur. I 2 3 4 5 6 7 8 9 l0 ll t2 l3 t4 l5 l6 l7 l8 l9 20 2t Another diagnostic tool used to analyze chemical sampling results as they relate to seawater intrusion is to evaluate the ratio of chloride to electrical conductivity. This analysis is especially suited for evaluating areas where extremely hard groundwater results in elevated chloride concentrations. The concept behind this tool is that electrical conductivity is directly related to the overall quantities of dissolved solids. For any given concentration of chloride, one would expect a Piper Normal Groundwater Slight Freshening Exchange Freshening Exchange Slight Conservative Mixing Conservative Mixing Slight lntrusion Exchange lntrusion Exchange Leve! Elevation (fr MsL)Min Max -29.3 5.1 6.5 2.0 20 5.7 3.1 16.0 18.1 34.0 5.5 4.6 6.2 5.7 139.3 44.4 300.7 7.5 5.4 6.6 8.6 Table 1. 1 0000 t0(x) much higher conductivity value if the chlorides were the result of very hard water due to the presence of other dissolved constituents. Figure l0 is a chloride vs. conductivity plot displaying the samples taken during the Phase II Assessment; sample points are color-coded based on the water level elevations as shown in the legend. Ghloride vs. Conductivity Waler Letel Eler-atron a .,. 'feet I{.SL c ? to l5 feet IUSL o,15frct}ISL X Cenh"l\\lidboy u =l+-=r+\iiv.d ',.{ [T-,,,;;n:\ .i' -4=s p"^':xH *&rl'.": 6tp&t*"O ) \T^. ' ta'e' " 100 1000 Condrctivity (psfcm) Figure 10. 10000 l'able 2 summarizes the results of this analysis, grouping results by the diagnostic technique presented in Figure 10, and comparing those results rvith average water levelelevations for each C:\My Documents\Word\WatershedPlanning\Seawater Intrusion (FinaI).doc 10. o E € roo -9 o 10 t00000 22 23 24 25 26 Editor: Doug Kelly 1 --;--- - {-- ,ir--v. _/ ryr1 * rit - - I 2 3 4 5 6 7 8 9 l0 ll t2 l3 14 l5 l6 l7 t8 SEAWATER INTRUSION TOPIC PAPER (Fina1) Approved by WRAC: 2/3105, Approved by BOCC 3/16/05 Island County / !flRIA 6 Watershed Planning Process group of results. This analysis was perforrned on data that excluded wells that are completed above sea level and those wells in Central Whidbey where anomalous chemistry is known to occur. Another method for evaluating water level elevation as a tool for seawater intrusion risk assessment is to compare water level elevation data to the conceptual rnodel for groundwater flow in a marine island environment as discussed earlier. The conceptual model predicts that water level elevations should be highest rrear the center of the island, with water levels dropping torvard the shoreline. The conceptual mcldel also predicts that if seawater intrusion was to occur in an area, it would occur first along the shoreline, moving inland as the situation worsens. -29.2 2.0 3.1 300.7 19.7 24. 012 I 6 8 l0 Horizontnl Scale in Feet x 1000 Normal (green) 16.2 Mixed (yellow) 7.9 Seawater lntrusion (red) 8.4 Table 2. Water Elevation lrx) l({t -llI llcsl \ l\1. Clrloride (loncentrations Figure I L Figure ll displays a section of Central Whidbey, with a map of Phase II well locations, and a vertical 'stick' diagram of well stratigraphy including elevations of the water table at each well C:\My Documents\Word\WatershedPlmning\Seawater Intrusion (Final).doc ll. b*i o t iI 0 Editor: Doug Kelly Water Level Elevation ai;!' I 2 3 4 5 6 7 8 9 l0 l1 l2 l3 l4 l5 l6 l7 l8 l9 20 2t 22 z.) 24 25 26 27 28 29 30 3l 32 JJ 34 35 36 )t 38 39 40 41 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/}s,Approved by BOCC 3/1.6/05 Island County / WRIA 6 W'atershed Planning Process represented by the blue triangles. The diagram shows that the water level elevation data is in good agreement rvith the conceptual model. Also shown at the base of each well in the stick diagram is the chloride concentration from that well. The elevated chloride concentrations in wells near the center of the island, including wells that are completed (screened) significantly above sea level (such as rvells AMU and ,A4U), represent the anomalous chemistry found in Central Whidbey wells discussed previously. Previous analysis of Central Whidbey that utilized chemistry as the primary analysis toolcorrectly identified those wells that were completed above sea level as being non- intrusion sources. However, those wells that were completed below sea level remained somewhat in question. Using water level elevation data provides clear differentiation between those wells that are impacted by intrusion and those that are not (false positives). One final analysis was performed on the data collected during the Phase Il Assessment. This analysis involved revierv of all available data including the various chemical analysis described above, water levelelevation, and when available. historicalchemistry data for analysis of variations in chernistry over time. Also included in this revielv rvas data fiorn other nearby wells that appear to be cornpleted in the same aquifer. For each well in the study, a detennination was made based on all available data as to the likelihood that the wellwas suffering from the irnpacts of seawaler intrusion. Wells were grouped into one of three categories as follows: Summary An s No Indications of Intrusion Inconclusive Indications of Intrusion Positive Indicators fbr Intrusion # of Wells 242 t0t 36 This analysis is used for two purposes: in study results discussions with each volunteer / participant in the Phase II Assessment, and in the statistical evaluation of water level elevation data presented in Section 5.1. Figure l2 presents a countywide view of the Phase II Assessment wells, grouped by water level elevations. With a few exceptions on North Whidbey (which will be discussed later in this paper). the elevation data closely conforms to the conceptual model. Virtually allthe red, orange and yellow data points (lower water level elevations) are located along the shorelines, while the green and cyan data (higher rvater level elevations) are located inland. Lower elevation data are almost always clustered in groups, indicating that these areas have reduced water level elevations. Water level elevation data can be used to identify 'false positives' in chernistry data, and in addition it can be used to identify 'false negatives'. Several shoreline areas on South Whidbey and Western Camano have relatively low water level elevations (red and orange data pclints), but as of now have not experierrced any chemical indications of intrusion. These areas can be interpreted as being at risk tbr intrusion, although intrusiclrr has not yet begun to occur. l,arger pro.iect propclsals in these lorv water level elevation areas should be evaluated fiom the perspective of searvater intrusion. Chloride data alone would not have provided this advance warning of pending intnrsion problerrrs, but instead could only react after intrusion actually begins to occur. Editor: Doug Kelly C:\My Documents\Word\WatershedPlmning\Seawater Intrusion @inal).doc 12' SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WR{C: 2/3/}S,Approved by BOCC 3/16105 Island County / WRIA 6 Watershed Planning Process Water Level Elevation O Very High (> 20) O High (8 to 20) O Medium High (6 to 8) O Medirrnr (:l to 6) @ Low(lto4) O VeryLor,v(< l) Feet Above Mean Tides 012145: Scale in Miles 'i to coovert f our lteail Tide L6:el ir the Pn$rel sormd to Nleao sjea Lel'el (NAVD 8E). add forlt feet to tlle lUeall Tide Lel'el lleasrrerrreut. I Figure 12 C:\My Documents\Word\WatershedPlanning\Seawater Intrusion final).doc 13. Editor: Doug Kelly J t*O-**dt* * 1 2 aJ 4 5 6 7 8 9 ll t3 15 17 l9 2t 23 25 27 29 3l 33 35 37 39 4t 43 44 45 46 47 48 49 50 5l 52 53 54 55 56 57 58 59 60 6l 62 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WR-{C: 2/3/05, Approved by BOCC 3/t6/05 Island County / WRIA 6 Watershed Planning Process An additional benefit of using water level elevation as a tool for evaluating seawater intrusion risk is the ability to define areas where intrusion is urrlikely to be an issue in the fbreseeable future. Areas in Figure l2 rvith cyan data points have water level elevations more than twenty feet above mean tide. 'fhese arcas are unlikely to suffer from intrusion" even when substantial withdrawals and drawdown occur. ln many cases, water level elevations can be pulled signiticantly belorv sea level at a pumping rvell and yet not induce seawater intrusion, as long as the water level elevations in the aquif'er rise high enough between the pumping well and the submarine aquifbr outcrop to prevent saltwater from entering into the aquifer. 'fhis situation creates what is known as a 'false interfbce' and is illustrated in Figure 13. The drawdown cone at the pumping ivell extends belorv sea level, which causes the Ghyben-Herzberg predicted interface position to move upward to the well screen. Water level elevations are significantly above sea level in the aquif-er between the well and the shoreline (A). resulting in the predicted interface position fblling significantly below the bottom of the aquifer (B), and preventing the movement of saltrvater to beneath the well, which prevents seawater intrusion at the well.Figure I 3. The important factor in preventing seawater intrusion is not the rvater level at the pumping well, but instead it is the water level in the area befween the well and the shoreline. If water Ievels in arr aquif-er are lorvered, reducing the pressure above sea level (A), the predicted interface position at (B) will rise until a critical level is reached where the base of the interface rises up to the base of the aquifer. Once the critical rise has been reached, intrusion of the pumping well will occur rather rapidly. Once rvater level elevations are lowered below the critical level and the seawater interface moves into the base of the aquifer beneath a pumping well, the strategies for mitigation change. From that point fonvard, attempts to control rather than prevent intrusion are required. Measures such as relocating wells, reducing purnping rates, and raising well intakes (screens) are typically ernployed. 'fhere is one additional conclusion can be drawn liom examination of the water level elevation study results: risk for intrusicln is highest near the shoreline, and decreases as you move inland. In some cases. wells currently showing signs of intrusion may exhibit intrusion problems even if they were the only wells completed in that particular aquifbr. In these cases, the problem is not so much one of over-drafting the aquifer. but rather one of poor selection of well location. These wells were initially installed into tlie zone of diffusion, and thus experienced elevated chlorides fiom the day they were installed. C:\My Documents\Word\WatershedPlmning\Seawater Intrusion (Final).doc 14. Water Level Elevations and False Interface Sea Level Editor: Doug Kelly Puget Sound Freshwater I 2 3 4 5 6 7 8 9 t0 1l t2 13 14 15 t6 t7 l8 t9 20 2l 22 z.) 24 25 26 27 28 29 30 31 5Z 33 34 35 36 )t 38 39 40 4t 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/)s,Approved by BOCC 3/1.6105 Island Counry / WRIA 6 Watershed Planning Process Figure l4 presents an example of this situation, with an aquifer with high freshwater florv discharging a substantial amount of water to the Puget Sound. Some of this freshwater discharge could be utilized as a water source, if the resultant movement of the interface could be tolerated. Two wells are shown in Figure l4: a shoreline well with its rvell screen positioned at tlie base of the aquifer and an inland well with an elevated screen. As in the previous example. pumping of the inland well, even at a substantial rate" will not result in intrusiorr of the inland well. In contrast. the shoreline well will sufl'er Figure 14 from intrusion. even rvhen pumped at a relatively low rate. Depending on the specific aquif-er conditiorrs and the distance of the second (inland) rvell, pumping of that well may induce drawdown on the shoreline well. Such drawdown would result in a worsening of intrusion problems for the shoreline well. Although the aquifer has significant capacity for additional withdrawals, the poor placement and subsequent intrusion of the shoreline well would be interpreted as a degradation of water quality. resulting in limiting future withdrawals from this aquifer in the immediate area. In fact, given the above-described scenario. the Washington Departrnent of Ecology (DOE) would not approve a water right application for the inland well, based on the degradation of water quality it would cause on the shoreline well. A loss of capacity can occur in aquifers that are not subject to seawater intrusion, where well construction can pose a limitation on the ability to utilize the resource. Take for example a well being constructed to supply water for a particular purpose; the well is drilled into a one hundred foot thick, highly productive aquifbr. Due to the aquifer's high productivity, it is only necessary to drilltwenty feet into the aquifbr in order to achieve the desired well production rate and the well is completed at that depth. Years later several new wells are completed lbr other purposes, and these withdrawals result in a lowering of the water table in the aquifer, and a reduction in the production capacity of the existing rvell. ln this situation, the aquifer is capable of supplying additional water to new wells, but in so doing these withdrawals would impair the ability of the existirrg wellto produce water. Under these circumstances, DOE would require that the existing well fully penetrate the aquifer, or in other words, the existing well owner could only claim an impairment if his well was screened at the base of the aquifer, allowing for full utilization of the resource. Seawater intrusiorr can be viewed as an inverted version of the partially penetrating well construction situation described above. An aquifer that could otherwise produce a significant quantity of water could be rendered useless due to "intrusion", caused by poor well placement and construction (too close to the shore, and/or too deep). If maximizing the use of groundwater resources is a desired goal, then a solution to this problem. similar to the fully penetrating solution described above. will need to be devised and implemented. C:\My Documents\Word\WatershedPlanning\Seawater Intrusion (Final).doc 15. Figure l5 Water Level Elevations and Well Placement Puget Sound Partial Penetration and lmpairmentFtt ,'7nril i l Editor: Doug Kelly Freshwater Drawdom Cone Aouif'er (sud) d _=--*- la(irllv Pcnclilng I 2 J 4 5 6 7 8 9 l0 l1 t2 l3 t4 l5 t6 t7 l8 l9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 JJ 34 35 36 3t 38 39 40 4t 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/}S,Approved by BOCC 3/16/05 Island County / WRIA 6 Watershed Planning Process Groundwater in lsland Counfy is too limited to waste due to poor well design and placement. Long- term strategies for resource rnanagement in a marine island environment need to include the concept of placing the points of withdrawal away from the shoreline, toward the center of the island where the risk for intrusion is less. Existing shoreline wells could be cc"rnverted to observation wells, for morritoring the position of the interface to insure that it is not moving inland further than desired. 5.0 Seawater Intrusion Policy - Revision Options The proposed Seawater Intrusion Policy is made up of three principal components as follows: l. Suggested Triggering Mechanism: A criterion for evaluating where the policy should or should not apply. Chloride concentrations and water level elevations are examples of potential triggering mechanisms. 2. Applicability: A criterion for evaluating what type of projects should be reviewed under the policy. Adding connections or creating new public water systems, drilling of new wells, and subdivision of land are examples of actions that could be reviewed for potential to cause / exacerbate intrusion problems. 3. Implications: A set of actions that result from triggering review of a project for which the policy applies. Testing, monitoring, hydrogeologic analysis, and phased development are some possible implications when an applicable proposal is flagged via the triggering mechanism. For each of these components, there exists a wide range of possible methods and implementation options. It is not possible in the context of this paper to discuss and review all of these potential options, so instead these discussions have taken place within meetings of the WRAC's groundwater subcommittee, and this paper reflects the resulting recommendations. To be effective, any policy needs to be easily understood and implemented. The simpler the regulation, the more likely it is to accomplish its goals. The current Seawater Intrusion Policy has a relatively complex implementation matrix with a total of l2 categories, with l4 options that can be required, potentially required, or recommended within each category. Recently, the Washington State Department of Health (DOH) has re-assessed its role in implementing the Seawater Intrusion Policy. DOH found that it has little legal authority to regulate public water systems based on resource protection issues, and as a result DOH no longer utilizes the 100 and 200 mg/l chloride triggering system, but instead relies on the 250 mg/l secondary MCL as a threshold for triggering management options. This has resulted in a situation where smaller Group B water systems (overseen by Island County Health) undergo more strenuous seawater intrusion testing / review than the larger Group A systems (overseen by DOH). In addition, discussions with DOH have revealed that even the 250 threshold currently utilized may not be enforced in the future. A new/revised Seawater Intrusion Policy needs to provide a rational and consistent approach for proposal review. C:\My Documents\Word\WaterehedPlanning\Seawater Intrusion @inal).doc 16. Editor: Doug Kelly 1 2 3 4 5 6 7 8 9 l0 ll 12 l3 t4 l5 l6 t7 l8 l9 20 2l 22 z) 24 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WR{C: 2/3/05, Approved by BOCC 3/1.6/05 Island County / WRIA 6 Watershed Planning Process Ultimately, the selection of trigger levels, applicability, and implications needs to balance the burden on applicants and regulators (costs involved with evaluating proposals for potential intrusion impacts) against some measure of the cost of having an aquifer intruded to any given level. Lower trigger values, wider applicability and more significant implications may increase costs for applicants and regulators, but will provide greater protection for groundwater resources. Conversely, higher trigger thresholds, more restricted applicability, and milder implications result in lower cost but provide less protection and may result in more severe intrusion problems prior to triggering regulatory protection measures. 5.1 SuggestedTriggeringMechanisms One goalof the Phase II Assessment was to evaluate the possibility of using water levelelevation as a tool for assessing seawater intrusion risk. Data collected during the Phase II Assessment indicate that there are areas in Island County where water level elevations are low, but as of yet the wells in these areas have not suffered from chemical impacts of intrusion such as rising chloride concentrations. It is possible that additional small withdrawals can be obtained in these areas without causing intrusion, and so these areas could be treated differently from areas where water levels are low and chemical impacts have occurred. The proposed triggering mechanism combines water level elevation data with chemistry data. Low risk areas would be defined as those areas with high water level elevations, regardless of chemistry. Under this triggering criterion, the false positive problems described earlier (where elevated chlorides result from process other than seawater intrusion) would be defined as low risk as long as the water level elevations in the area were above the triggering threshold. Medium risk areas would be those areas where water elevations fall below some triggering threshold, while high risk would be defined as areas with lower water level elevations and elevated chloride concentrations. A new category, very high risk, will be defined where water levels are low and chloride concentrations reach a more severe level. The chloride concentration trigger levels (100 and 200 mg/l) utilized by the current policy to define medium and high-risk areas were likely selected (on the high side) with the issues related to false positives and non-intrusion sources in mind. Using water level elevation as the initial screening criteria may reduce or eliminate these problems, enabling the use of a more conservative (lower) threshold chloride concentration (trigger). Alternatively, selecting a relatively high trigger level such as 250 mgll would provide consistency with current DOH guidelines and the EPA secondary MCL for chloride. One could argue that any selected trigger level will - in the long run - be met or exceeded in many coastal areas laquifers since certain types of development will continue to occur without regard for intrusion while concentrations fall below the selected trigger level. (see Section 6.0) One option for defining a trigger value for chloride would be to couple the trigger to health risks presented by intrusion. The U.S. EPA is responsible for setting maximum contaminant levels (MCL) for drinking water, with primary MCL values representing health risk standards, while secondary MCL's are esthetic (taste, odor, color etc.) standards. The EPA has set a secondary MCL Editor: Doug Kelly C:\My l)ocuments\Word\WatershedPlanning\Scawater Intrusion (Final).doc 17. 25 28 26 27 29 30 31 .tz 33 34 35 36 37 38 39 40 4l 42 43 44 45 1 2 3 4 5 6 7 8 9 l0ll 12 13 t4 l5 l6 l7 l8 t9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 JJ 34 35 36 37 38 39 40 4t 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by IVRAC: 2/3/05, Approved by BOCC 3/1,6/05 Island County / WRIA 6 l7atershed Planning Process for chloride at250 mg/l based on taste thresholds. Although the EPA considers sodium a primary (health risk) contaminant, they have not set an MCL for sodium, but rather have issued a recommended level of 20 mgll for those consumers who may be restricted for daily sodium intake. Using water quality data from sampling marine waters around Island County, the ratio of chloride to sodium in these waters is approximately 1.8 mg/l of chloride for every mg/l of sodium. Using this ratio to extrapolate the chloride concentration that would accompany 20 mgll of sodium yields a concentration of 36 mg/l chloride. Despite the logical link to health effects, a chloride trigger level as low as 36 mg/l would only be feasible if it makes sense from the perspective of groundwater chloride concentrations in groundwater that is not impacted by seawater intrusion. A second analysis was performed to assess Island County groundwater chloride concentrations. This analysis utilized all chloride and conductivity sampling data on file, first filtered to include only those water samples that appear to be normal groundwater (not intruded) based on chloride vs. conductivity ratios (see Figure l0), wells that are completed below sea level, and excluding Central Whidbey wells. The mean chloride concentration in these water samples was 38.8 mg/l with a standard deviation of 30.6. Adding two times the standard deviation to the mean value yields the statistical value below which 97.5% of all samples will fall, which calculates to be 100.0 mg/I. An idealized graphicalrepresentation of this concept is presented as a frequency ofoccurrence plot in Figure 16. The horizontal axis displays chloride concentrations while the vertical axis displays the frequency of occurrence, with higher points on the curve representing concentrations that occur more frequently. The peak of the curve represents the mean or average chloride concentration (38.8 mg/l), and moving two standard deviations to the right defines the value (100 mgil) below which 975% of allsamples will fall (hatched area). I {)o C)F oo-+{ >ro o o I The mean chloride concentration in Island County (38.8 mg/l for non-intruded wells) is very near the trigger level derived using the sodium health based chloride criteria (36 mg/l). As a result this 38.8 l()() Chloride (rng/l) Figure 16 trigger cannot be utilized since its use would identiff nearly half of all non-intruded wells as exceeding this value. However, the chloride concentration analysis does provide a possible trigger, the chloride concentration for which the vast majority of wells that are not suffering from intrusion would fall below. Selecting a value of 100 mg/l would provide a fairly conservative triggering mechanism, yet have relatively few false positives. This value also has the advantage of having been utilized by the current policy and thus has some level of public acceptance. A water level elevation triggering value also needs to be selected in order to incorporate this tool into the seawater intrusion policy. Data pertaining to water level elevations and intrusion levels are available from the Phase II assessment. In this case, elevations lower than the trigger level will be interpreted as having risk for intrusion, so the evaluation will target maximum water level elevations C:\My Documents\Word\ri0ateshedPlmning\Seawater Intrusion final).doc 18. 2 Standard Deviations Mean (Average) 97.5% of all samples Editot: Doug Kelly I 2 J 4 5 6 7 8 9 l0 ll 12 l3 t4 l5 l6 l7 l8 l9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 SEAWATER INTRUSION TOPIC PAPER (Finat) Approved by WRAC: 2/3/05, Approved by BOCC 3/1.6/05 Island County / WRIA 6 Watershed Planning Process in wells that are known to be intruded. Using the methodology outlined above, the mean water level elevation in wells classified as having positive indicators for intrusion (see page 12, lines l0 - 25) is 5.6 feet above mean sea level (MSL, NAVD 88) with a standard deviation of 1.4 feet. Adding fwo times the standard deviation to the mean yields a value of 8.4 feet MSL, below which 97 .5% of the water level elevations for intruded wells would fall. It should be noted that the mean sea level datum does not equal mean tide level in the Puget Sound. The National Geodetic Survey (NGS) maintains tidal benchmarks around the Puget Sound, and these benchmarks have information relating to various vertical datum including NAVD 88 and the mean tide levels. The mean tide level in the Puget Sound varies spatially, but typically in the area of Island County the mean tide level is at just over four feet on NAVD 88. Thus the 5.6 feet level identified in the previous paragraph equates to just over 2 feet above the mean tide level. Using the criteria defined above, the new Seawater Intrusion Policy would be defined as follows: Risk Cateqorv Low Medium High Very High Water Level Elevation t Greater than 8.4 Less than or Equalto 8.4 Less than or Equal to 8.4 Less than or Equalto 8.4 Table 3. Chloride Concentration 2 Any' Less than 100 Between 100 and 250 Greater than 250 rWater Level Elevation in feet above Mean Sea Level (MSL) NAVD 88. +4 feet MSL: 0 feet relative to Mean Tide Level in the Puget Sound. For example, 8.4 feet MSL: 4.4 feet above Mean Tide Level. '?Chloride Concentration in Milligrams per Liter (mg/l) 3 Where water level elevations are greater than 8.4 feet, chloride concentrations are irrelevant The current Seawater Intrusion Policy defines risk areas by placing % mile radius circles around wells with elevated chloride concentrations; utilizing circles has worked reasonably well and is easily implemented. The new policy would maintain this strategy, utilizing %mile circles around wells with low water level elevations, and wells with elevated chloride concentrations. The combined overlay of the chloride and water level elevation maps will be used to define risk areas. A preliminary map generated using the above criteria is presented in Figure 17 . Of particular interest on this map are the green and yellow areas. Green areas are areas with elevated chloride concentrations but high water level elevations, previously described as 'false positives', such as Central Whidbey Island south of Coupeville. Yellow areas represent areas with low water level elevations, but without elevated chlorides; these areas are considered to be 'false negatives' or C:\My Documents\Word\WatershedPlmning\Seawater Intrusion (Final).doc 19. Editor: Doug Kelly SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/ll,Approved by BOCC 3/16/05 Island County / nfRIA 6 Watershed Planning Process 1 Legend iv.ry High Risk ffiHigL nisk (ltvtedium Risk (-)Lo.o,Risk (Previously Mediurn or High ($lownrsk Ifnf cerrairl?il rnrlrzl'3,lrrr litxn l;rnrurry 1t't)S I 2 J 4 5 Revised Seawater Intrusion Policy 'Circle Map' Utilizing Water Level Elevation and Chloride Data Figure 17. C:\My Documents\Word\WatershedPlanning\Seawater Intrusion @inal).doc 20. Editor: Doug Kelly I 2 3 4 5 6 7 8 9 l0 ll t2 l3 l4 l5 l6 t7 l8 t9 20 21 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 37 38 39 40 4t 42 43 44 areas where intrusion risk is present but intrusion has yet to be identified based upon existing data. It should be noted that ICHD currently has significantly more chloride data available than water level elevation data. In particular, certain areas of the county have no water level data but do have chloride data. If the chloride concentrations in these areas are elevated (but there is no water level data), then these areas are mapped as green or low risk. Without water level information it is uncertain if these areas are truly represented as low, medium or high risk. Water level data elevation must be collected in these areas to determine what risk category should actually apply. Examples of where this problem is likely occurring are portions of the panhandle on Camano Island, and in the kettles region west of Penn Cove on Whidbey Island. A lack of water level elevation data occurs most frequently in areas where larger public water systems are present, such as within the service area for the City of Oak Harbor, and in the area of NAS SEAWATER INTRUSION TOPIC PAPER (Final) Approved by !7RAC: 2/3/05, Approved by BOCC 3/1.6/05 Island County / WRIA 6 Watershed Planning Process I WLE Data Available D NoWLE Data Figure 18 Whidbey Island. A map showing water level elevation data coverage is presented in Figure 18. The need for additional water level elevation data to fill these information gaps is discussed in Section 5.3. 5.2 Applicability Based on the factors influencing seawater intrusion presented in Section l.l, it is clear that once an aquifer reaches a critically low water level elevation, any groundwater withdrawal has the ability to induce intrusion. Areas that have water level elevations above this minimum (low risk in Table 3) are not at risk for intrusion, and so proposals within these areas would not be subjected to review for seawater intrusion. Medium risk areas as defined in Table 3 have low water level elevations, but have yet to experience any groundwater quality (chlorides are below 100 mg/l) impacts. Proposals that withdraw relatively smaller volumes of water have a lower potential for impact, and therefore do not pose as high a risk to a marginally adequate aquifer as larger proposed withdrawals. As such, smaller proposals that would potentially add 6 or less equivalent residential units (ERU) would be allowed to occur in a medium risk area, but those proposals that would include more than six connections would be subject to review. Exempted proposals include subdivisions of up to six lots, addition of up to six connection approvals to an existing water system, or creation of a new water system with up to six connections. Note that the above description defines the expansion of a water system, which entails the addition of new connection approvals (either within or outside of the systems defined service area), not the putting to use of previously approved but currently unused connections. It is anticipated that in most cases, connecting to C:\My Documents\Word\WatershedPlanning\Seawater Intrusion (Final).doc 21. Editor: Doug Kelly I 2 aJ 4 5 6 7 8 9 l0 ll t2 l3 t4 l5 l6 17 18 19 20 21 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 37 38 39 40 4l 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WR{C: 2/3/05, Approved by BOCC 3/1.6/05 Island County / !fRIA 6 Watershed Planning Process systems that are growing into previously approved connections will occur on a house-by-house basis, and will generally occur at a relatively low rate. High-risk areas as defined in Table 3 have low water level elevations and have chloride impacts between 100 and 250 milligrams per liter. In this situation, even smaller (6 ERU's or less) proposals can potentially push the aquifer into significant deterioration due to seawater intrusion. In high-risk areas, any proposal that would add more than I ERU, which includes subdivision of land, creation of any new public water system, and expansion or infilling of public water systems would be subject to review. In addition, individual wells on parcels of less than 1.5 acres in size would also be reviewed in high-risk areas. Very high-risk areas are defined as having low water level elevations, and chloride concentrations in excess of 250 milligrams per liter in the source of water that is used for the proposal. In this situation, the well has reached a significant level of contamination, and the potability of the water begins to come into question. Water systems with chloride concentrations greater than 250 milligrams per liter would be placed on moratorium (no new connections allowed) until the situation can be remedied or mitigated. Individual wells on parcels less than five acres in size will also be subject to review. Chloride concentrations in wells that are impacted by seawater intrusion typically peak during the late summer and drop off during the winter months. In most cases, this is not due to changes in recharge to the aquifers, because the traveltime (the time it takes a raindrop to move down through the overlying stratigraphy to recharge an aquifer) is on the order of years. The annual rise and fall of chloride concentrations is actually caused by the increase in pumping associated with lawn watering and other seasonal water use. For this reason, a drop in chloride concentration associated with seasonalvariation will not, on its own, be considered a mitigation of seawater intrusion. The applicability of the policy as defined above primarily targets the subdivision of land, and creation or expansion of water systems (including individual wells under certain circumstances). All of these actions involve the use of additional groundwater resources associated with growth, or the addition of new buildings and/or residents within the county. It is acknowledged, however, that existing water users within an area suffering from seawater can contribute to intrusion problems, and that placing the burden of finding and implementing remedies solely on those systems that are expanding may not be equitable. For example, two existing adjacent public water systems may have wells completed in the same aquifer. If this aquifer begins to suffer from seawater intrusion, and one of the systems desires to add new connections, that system could be required to find and implement mitigation measures to avoid further intrusion. If the other system has no plans to expand, currently no mitigation would be required even if the system operated in a manner that exacerbated the problem. Ideally, measures to mitigate seawater intrusion would be enacted by all users of the impacted resource, regardless of whether or not growth is occurring in an area. In reality, state and local governments have limited legal authority to regulate groundwater withdrawals unless they are C:\My Documents\Word\WatershedPlmning\Seawater Intrusion final).doc 22. Editor: Doug Kelly I 2 3 4 5 6 7 8 9 10 ll t2 l3 l4 l5 r6 t7 18 l9 20 2t SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRdC: 2/3/05, Approved by BOCC 3/1.6/05 Island County / WRIA 6 Watershed Planning Process either applying for a permit (such as a development permit) or they are in violation of state water law (conservation, beneficial use, etc.). As such, voluntary participation in mitigation efforts should be encouraged, and strategies for long-term regulatory mechanisms should be investigated. This investigation must take into account the legal mechanisms and limitations associated with a more holistic groundwater management effort that identifies existing management tools and the relationship between State Water Law and Groundwater Degradation. 5.3 Implications It is proposed that public water systems (3 or more connections) that have sources (wells) that fall within medium, high, or very high risk areas would be required to collect water samples from these sources in April and August of each year, and submit those samples to a state certified laboratory for chloride and conductivity analysis. Water level elevation data would be collected from all potentially regulated projects other than individual wells. (See Figure 19.) Proposed projects that fall within risk areas as defined in Section 5.1, and meet the applicability criteria defined in Section 5.2, will be evaluated to determine if the proposed withdrawal will negatively impact the aquifer by inducing or worsening seawater intrusion. In most cases this evaluation will require the collection and analysis of data pertaining to the well and the aquifer in which the well is completed (screened). Water Level lianrtrlins Searrater Intnr sion Relieut Elevations Figure 19. C:\My Documents\Word\WatershedPlanning\Seawater Intrusion (Final).doc 23. Conn6 ections More than 1 ConnectionHigh Low Medium April ancl August Chloricle and Condtrctivity Sarnpling trorn all PWS rvith N,lore thur Trvo Connections, in Ir,{eclium or Higher Risk fueas Data Collection trncl will to Araly5i5 6311 Earl Phaseclbe Provideto valnationEv ivillPrr>j ect Aquifer (Cause \\iells rvill Pr,:r'ir.{e Water Leve1 Eler.iltion Data Other than 22 23 Editor: Doug Kelly More than 6 Lots Ail Ail < 5 acres New or Expandinq PWS lndividualWells none Ve h none none I 2 3 4 5 6 7 8 9 l0 ll t2 l3 t4 15 l6 t7 18 t9 20 2l 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 37 38 39 40 4t 42 43 44 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRA,C: 2/3/}5,Approved by BOCC 3/1,6/05 Island County / !7RIA 6 Watershed Planning Process It is worth noting that implementation of the current Seawater Intrusion Policy has changed substantially since the policy was initially developed. When the policy was initially adopted, Island County Health did not have a professional hydrogeologist on staff to assist in evaluating projects. As a result, all applicable projects that were found to be at risk (medium or high risk as defined by the current policy) were required to supply a full hydrogeologic assessment of their project. Now that the department has hydrogeologic expertise, projects that fall under review can be screened for the applicability of the policy to the specific project. Smaller quantities of initial data can be collected at a greatly reduced cost and an initial determination can be made as to the need for additional data based on the preliminary results. This can result in a significant savings for some applicants, while allowing other applicants to make informed decisions on whether or not to pursue the additional data collection (with the associated costs) given the results of the preliminary testing, or perhaps to evaluate other more promising courses of action. This methodology of phased review and staged data collection (and incremental costs associated with this data) is expected to continue regardless of any potential modifications to the triggering requirements. If a proposed project were determined to be at risk based on the preliminary data, aquifer testing and analysis would be required to determine the hydraulic characteristics of the aquifer. The results of this testing will be used to evaluate the long-term impacts the proposed withdrawalwill have on the aquifer and nearby wells. The aquifer testing and impact prediction analysis would result in a hydrogeologic report; a hydrogeologist licensed in the State of Washington should prepare this report and oversee the aquifer testing and analysis. The specific details of data collection and analysis requirements will be determined on a case-by-case basis. Costs associated with data collection and analysis will be borne by the applicant. 6.0 Options Option #l No Action The no-action option relies on the continued use of the current (chloride based) seawater intrusion policy. This option has both benefits and drawbacks; the primary benefit is ease of implementation. The drawbacks associated with this option relate to the shortcomings of the current seawater intrusion policy discussed earlier in this paper. These are the false positives (elevated chlorides identiffing areas as being at risk for intrusion where no risk exists) and false negatives (the failure to identiff risk until after intrusion occurs). This option has low additional cost and moderate to low effectiveness. Option #2 Seawater Intrusion Policy Modifi cation This option involves modification of the Seawater Intrusion Policy to include the use of water level elevation as described in Section 5 of this paper. As with the no-action option, modification of the Seawater Intrusion Policy has both advantages and disadvantages. The primary drawback for this strategy is the increased cost to the applicant. Although depth to C:\My Documents\Word\WatershedPlmning\Seawater Intrusion final).doc 24. Editor: Doug Kelly I 2 J 4 5 6 7 8 9 l0 ll l2 l3 t4 l5 l6 t7 l8 t9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 33 34 35 36 37 38 39 40 4t 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by !7R.{C: 2/3/05, Approved by BOCC 3/1.6/05 Island County / !(iRIA 6 Watershed Planning Process water measurements are relatively easy and inexpensive to obtain, the surveying of measuring point elevations will result in additional expense. Advantages to modifuing the Seawater Intrusion Policy far outweigh the disadvantages, and include the elimination of false positives (flagging of proposals for risk where in fact none exists) and of false negatives (flagging of proposals that present risk that were previously missed). Modifring the Seawater Intrusion Policy will provide security for those systems that are not at risk for intrusion, and give direction to those seeking a more adequate water supply. The current Seawater Intrusion Policy was approved and adopted by agreement between the Health Services Director for the Island County Health Department and the Manager of State Department of Health, Northwest Region, Drinking Water Operations. Modifications to policy could be accomplished through several approaches, each having distinct advantages and disadvantages. These options include the development of a new joint policy, the development of an Island County policy, adoption of a Resolution by the Board of Island County Commissioners, or the inclusion of the review criteria into Island County Code. This option is anticipated to have moderate cost and high effectiveness. Option #3 Monitoring Network Modification Island County Health currently operates a long-term groundwater-monitoring network. This network is meant to provide data for analysis of long-term trends in groundwater quality and quantity. The network is composed of individual and group domestic water supply wells. At the time that the nefwork was developed, chloride concentration was selected as the tool for evaluating seawater intrusion trends. Water level elevation will provide an earlier warning of pending intrusion problems for aquifers that occur below sea level, and also provide warning of dewatering (lowering of water levels) in above sea level / perched aquifers. Because the current network utilizes water supply wells as its monitoring points, small-scale trends (on the order of fractions of a foot per year) are virtually impossible to detect. This is because the wells are almost always in a state of recovery from some pumping prior to monitoring. For example, if a well had been pumped an hour prior to monitoring, it may have recovered to with a l0m of a foot of static, but if it had been pumped l5 minutes prior to monitoring it may be one half foot below static. Dedicated monitoring wells located some distance from larger water supply wells would always be static since they would not be pumped other than for sampling. As a result, they would provide much higher quality data pertaining to seasonal and long-term water level changes. Water quality data (chloride concentrations) collected from wells that are subject to intrusion is highly dependant on the timing and duration of pumping prior to sampling. Thus a water supply well could be sampled twice during a 24-hour period, and different chloride values may be obtained depending on how much the well had been in use prior to the arrival of the sampling staff. Dedicated monitoring wells would not suffer from this problem, since the wells would not be in use prior to sampling and the values obtained would be much more consistent and comparable. Using a network of dedicated monitoring wells, the quality of data obtained from the network would be significantly improved, with detection of trends in water level or chemistry C:\My Documents\Word\WatershedPlanning\Seawater Intrusion (Final).doc 25. Editor: Doug Kelly I 2 3 4 5 6 7 8 9 l0 lt t2 l3 t4 l5 16 17 l8 l9 20 2t 22 Z) 24 25 26 27 28 29 30 31 32 33 34 35 36 5t 38 39 40 4t 42 43 44 45 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WR{C: 2/3/}S,Approved by BOCC 3/1,6/05 Island County / !7RIA 6 Watershed Planning Process at a much earlier point / lower level. Early detection of trends in water level and / or chemistry is a critical element of a successful groundwater resource management program. This option is considered high cost and high effectiveness. Option #4 Uniform Application of Seawater Intrusion Review Regardless of how the current Seawater Intrusion Policy is modified to include water level elevation data, the resultant policy/resolution/code should be applied uniformly to all water system developments, including those currently outside the purview of the Island County Health Department (i.e. Group A Systems). Island County, along with DOH and DOE, needs to formally address how the seawater intrusion protection strategy will be applied to developing Group A water systems. ICHD currently reviews individual wells, smaller water systems (2 to l4 connections/Group B), and land subdivision proposals. ICHD review of these projects from the perspective of seawater intrusion is expected to continue in the future. DOH provides oversight of larger (Group A) public water systems, while the DOE provides oversight of the water resources of the state including the review of water right permit applications. DOH has recently re-assessed its partner role in implementing the Seawater Intrusion Policy. DOH has determined that it has legal authority to regulate public water systems based on public health issues only (i.e. not on any resource protection issue basis). Most Group A water systems in Island County are required to obtain a water right permit from DOE. When the aquifer proposed for use is at risk for seawater intrusion, DOE generally applies provisions relative to seawater intrusion, including monitoring requirements. In the event of rising chloride concentrations, the provisions allow DOE to require mitigation / corrective action. If mitigation measures are not successful in controlling the increasing chloride concentrations, DOE has the ability to freeze the system at the current stage of development. Some older water right permits may not contain specific provisions related to seawater intrusion. In these cases DOE still has the ability to provide resource oversight based on the water quality / anti- degradation policy (WAC 17 3-200-030). The proposed mechanism for review of Group A water systems involves utilizing DOE's technical staff and regulatory authority to provide oversight of Group A water systems when review is triggered by the seawater intrusion policy. Three agencies would be involved in this process; Island County Health would maintain the policy maps (circle maps) that identiff risk areas; DOH would utilize these maps to evaluate what water system actions would result in a need for seawater intrusion review; and, when triggered, DOE would provide the technical resource review. The details of this arrangement would be outlined within an interagency agreement or Memorandum of Understanding between the three agencies and should be explored further during the implementation of the watershed plan.. Prior to the initiation of such an agreement it is imperative to fully understand the legal basis of applying limitations on withdrawals as they pertain to existing water rights. This option is anticipated to have low cost and high effectiveness. C:\My Documents\Word\WatershedPlanning\Seawater Intrusion f inal).doc 26. Editor: Doug Kelly I 2 J 4 5 6 7 8 9 l0 ll t2 l3 t4 l5 t6 l7 l8 l9 20 2t 22 23 24 25 26 27 28 29 30 3l 32 JJ 34 35 36 SEAWATER INTRUSION TOPIC PAPER (Final) Approved by WRAC: 2/3/)S,Approved by BOCC 3/16/05 Island County / !fRIA 6 Watershed Planning Process Option #5 Future Policy Recommendations As Island County aquifers are recharged annually by rainfall, it is important to manage withdrawals so that they do not exceed sustainable yields. To support this goal, Island County should develop valid and verifiable thresholds, using chloride levels and water levels above sea level, as indicators that water withdrawals are exceeding recharge, which reflects a depletion of fresh or potable water supplies from county aquifers. To reverse such possible depletion, Island County should pursue the development of incentives and regulations which, in applying to all freshwater withdrawals within an area where the freshwater within an aquifer is being depleted, would implement water use reductions to both prevent further depletion and return the aquifer to a maintainable water balance. Due to legal and administrative hurdles, this option is not feasible at the current time. However the WRAC recognizes the need for such policies and recommends that strategies to overcome these hurdles be pursued. 7.0 Conclusions Island County has historically taken a leading role in understanding and protecting its groundwater resources, particularly in the area of seawater intrusion. The adoption of the Seawater Intrusion Policy in 1989 represented a significant step toward this goal of protecting our aquifers. This topic paper attempts to provide an overview of current science and regulations, and makes recommendations for future resource protection efforts. Specifically this paper provides recommendations for updating the Seawater Intrusion Policy to incorporate additional analysis tools, and to simpliff and streamline the use of the policy. These changes result in a tool that overcomes many of the problems associated with the current policy. Both the current policy and the proposed policy revisions define a screening tool used to evaluate risk for seawater intrusion and trigger additional review where needed. Neither the current policy nor the proposed policy revisions are meant to draw conclusions regarding the likelihood of seawater intrusion posed by any particular proposal. As in the case of the 1989 seawater intrusion policy, science, technology, regulatory and political issues continuously change through time. The recommendations of this paper should not be taken as static and final, but only one step in a long-term strategy of adaptive management, critical to the protection of our water resources into the future. C:\My Documents\Word\WatershedPlmning\Seawater Intrusion (Final).doc 27. Editor: Doug Kelly