Delineating Recharge to a River Valley Aquifer by Riverine Seismic and EM Methods

Butler, Karl E.; Nadeau, Jean-Christophe; Parrott, Russell; Daigle, Annie E.

doi:10.4133/jeeg9.2.95

Cited by 24 publications

(16 citation statements)

References 7 publications

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“…Hurwitz et al (1999) have described results obtained from a floating TEM system first described by Goldman et al (1996). Their system investigated between depths of 10 and 100 m. In a study of aquifer recharge Butler et al (2004) employed the Geonics EM31 and EM34 (Frequency domain EM systems) which allowed efficient mapping of horizontal variations in apparent conductivity, but this allowed no vertical resolution of conductivity. DC Resistivity arrays have previously been employed in floating configurations (Allen and Merrick, 2003;Dyck et al, 1983;Amimoto and Nelson, 1970).…”

Section: Introductionmentioning

confidence: 99%

River sediment salt-load detection using a water-borne transient electromagnetic system

Barrett¹,

Heinson²,

Hatch³

et al. 2005

Journal of Applied Geophysics

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Section: Introductionmentioning

confidence: 99%

River sediment salt-load detection using a water-borne transient electromagnetic system

Barrett¹,

Heinson²,

Hatch³

et al. 2005

Journal of Applied Geophysics

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“…Using resistivity imaging along the shoreline, and seismic and electromagnetic profiling on the river, Butler et al (2004) have confirmed the presence of several windows in the riverbed in the vicinity of the municipal well field.…”

Section: Study Sitementioning

confidence: 69%

“…No municipal production wells appear on this cross section. (source: Butler et al, 2004). during the data collection period shown in Fig.…”

Section: Figurementioning

confidence: 99%

See 1 more Smart Citation

River sediment and flow characteristics near a bank filtration water supply: Implications for riverbed clogging

Goldschneider

Haralampides

MacQuarrie

2007

Journal of Hydrology

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“…Use geophysical surveys to identify geological variations. Use boat-towed continuous seismic reflection, electromagnetic (EM) methods, and ground penetrating radar (GPR) to determine geological contacts and clay versus sand contents, "Delineating Recharge to a River Valley Aquifer by Riverine Seismic and EM Methods," (Butler, et al 2004), "Use of Ground-Penetrating Radar and Continuous Seismic-Reflection Profiling on Surface-Water Bodies in Environmental and Engineering Studies," (Haeni, 1999). Although attempts to use GPR along the shoreline were deemed unsuccessful, because of lack of penetration (perhaps due to attenuation of the signal by clay), the method should be reevaluated for use, because in places where GPR does penetrate, it may indicate either loose fluvial sandy deposits or perhaps preferential discharge locations, (Conant 2004) where more permeable deposits are present and the armored layer is absent.…”

Section: Suggestions Regarding Characterization Ofthe Cr+mentioning

confidence: 99%

Technical Evaluation of the Interaction of Groundwater With the Columbia River at the Department of Energy Hanford Site 100-D Area

Sw¹

2008

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EXECUTIVE SUMMARY BACKGROUND AND OBJECTIVESGroundwater beneath much of Hanford's 100 Areas is contaminated with hexavalent chromium (Cr+ 6 ) as a consequence of treating reactor cooling water to prevent corrosion. The Cr+ 6 is thought to have infiltrated the subsurface through disposal of reactor cooling water in ponds or through spills in areas where Cr+ 6 solutions were mixed. Several treatment systems are in place as interim remedial actions to remove Cr+ 6 from the groundwater. These systems don't capture groundwater that has already passed down-gradient from or outside ofthe system's influence, which is the focus of this report. Some of this impacted groundwater is currently discharging to the Columbia River and some will continue to discharge in the future until sources are depleted or remediated.Cr+6 is highly mobile and toxic to aquatic organisms, including benthic and hyporheic-zone aquatic life residing on and in the river bed, as well as salmon eggs and alevin in redds and river spawning beds. Of concern is the fate of Cr+6 as it discharges to areas within the channel of the river, because sensitive species inhabit the river and its associated transition zone. The aquatic standard for Cr+ 6 is 11 ug/l under the current Record of Decision (ROD) for Interim Action.In April 2008, an expert panel of scientists was convened to provide observations and suggestions intended to improve the current understanding of groundwater-surface water interactions in the 100 Areas (primarily focusing on 100-D Area), and to identify what additional analyses or approaches may provide critical information needed to design and implement effective remediation systems that will minimize impacts to river aquatic systems. The panel was asked to evaluate the likely mechanisms that control the locations, timing, and quantity of contaminated groundwater that enters the riverbed and suggest how current data sets and interpretations and possibly new data sets and interpretations would facilitate remediation of Cr+ 6 -impacted groundwater and reduce negative impacts to the river aquatic system. In this context, they were tasked to:• evaluate past and current conceptual models of the interaction of local near-bank groundwater with the Columbia River;• evaluate past and current data collection methods, data analysis techniques, assumptions, and groundwater transport and mixing mechanisms;Evaluate the current monitoring network;• evaluate the role played by modeling; and,• recommend additional research to fill existing data gaps.The expert panel's report is organized as follows:• The Conceptual Model Framework• Data Acquisition, Network Design, and Data Analysis In the report, the panel provides observations and suggestions that are intended to enhance understanding of how the interaction of site groundwater and the Columbia River could influence remedial technology selection, design, operation, and evaluation. The panel is aware that extensive data sets, field investigations and analyses have already been completed at the 100 Area sites...

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Delineating Recharge to a River Valley Aquifer by Riverine Seismic and EM Methods

Cited by 24 publications

References 7 publications

River sediment salt-load detection using a water-borne transient electromagnetic system

River sediment salt-load detection using a water-borne transient electromagnetic system

River sediment and flow characteristics near a bank filtration water supply: Implications for riverbed clogging

Technical Evaluation of the Interaction of Groundwater With the Columbia River at the Department of Energy Hanford Site 100-D Area

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