File list
This special page shows all uploaded files.
| Date | Name | Thumbnail | Size | Description | Versions |
|---|---|---|---|---|---|
| 16:54, 7 April 2020 | Adamson and Newell 2014 ER-201211.pdf (file) |  |
13.52 MB | Adamson, D.A., and Newell, C.J., 2014. Frequently Asked Questions about Monitored Natural Attenuation in Groundwater. Environmental Security Technology Certification Program (ESTCP), | 1 |
| 16:49, 1 April 2020 | Yuncu1w2Fig6.png (file) |  |
202 KB | Figure 6. Limit of Migration of Dissolved Hydrocarbon Plumes (Newell and Connor 1998). | 1 |
| 16:48, 1 April 2020 | Yuncu1w2Fig5.png (file) |  |
367 KB | Figure 5 - Free Product Collecting in the Basin of an Underground Storage Tank | 1 |
| 16:46, 1 April 2020 | Yuncu1w2Fig4.png (file) |  |
224 KB | Figure 4 - TPH Fractions of TCEQ Method 1006. Adapted from Rhodes (2006) | 1 |
| 16:44, 1 April 2020 | Yuncu1w2Fig3.png (file) |  |
170 KB | Figure 3 - Fractional Distillation of Crude Oil in Fractionating Column | 1 |
| 16:43, 1 April 2020 | Yuncu1w2Fig2.png (file) |  |
510 KB | figure 2 - diesel fuel | 1 |
| 20:17, 23 March 2020 | Lotufo1w2Fig13.png (file) |  |
1.11 MB | figure 13. POCIS sampler with weighted anchor system adjacent to the base of a 500 pound "old style" general purpose bomb | 1 |
| 20:16, 23 March 2020 | Lotufo1w2Fig12.png (file) |  |
721 KB | figure 12. Stations (15 in total) in Bahia Salina del sur where POCIS were deployed. | 1 |
| 20:14, 23 March 2020 | Lotufo1w2Fig11.png (file) |  |
775 KB | Figure 11. Biofouling did not affect POCIS uptake of TNT or RDX (Rosen et al. 2018) | 1 |
| 20:13, 23 March 2020 | Lotufo1w2Fig10.png (file) |  |
130 KB | Figure 10. POCIS-determined MC concentrations from the controlled field demonstration | 1 |
| 20:12, 23 March 2020 | Lotufo1w2Fig9.png (file) |  |
347 KB | Figure 9. Location of POCIS surrounding Composition B source during controlled field demonstration | 1 |
| 20:10, 23 March 2020 | Lotufo1w2Fig8.png (file) |  |
911 KB | Figure 8. 15g of Composition B (left) placed in mesh bag (right) as used in the controlled field demonstration | 1 |
| 20:09, 23 March 2020 | Lotufo1w2Fig7.png (file) |  |
905 KB | Figure 7. Controlled field demonstration site, Santa Rosa Sound, Florida. | 1 |
| 20:08, 23 March 2020 | Lotufo1w2Fig6.png (file) |  |
691 KB | Figure 6. Experimental determination of MC release rate from a perforated munition in a large flume | 1 |
| 20:06, 23 March 2020 | Lotufo1w2Fig5.png (file) |  |
1.11 MB | Figure 5. Flume setup for optimization of POCIS and determination of MC sampling rates | 1 |
| 20:04, 23 March 2020 | Lotufo1w2Fig4.png (file) |  |
501 KB | Figure 4. Sample holder (left)( and protective canister for multiple POCIS (right, both supplied by EST) | 1 |
| 20:00, 23 March 2020 | Lotufo1w2Fig3.png (file) |  |
119 KB | Fiugre 3. The structure of a POCIS where stainless steel encompasses the PES membranes and the adsorbent in the middle (from Morin et al. 2012 and Seethapathy et al. 2008) | 1 |
| 19:58, 23 March 2020 | Lotufo1w2Fig2.png (file) |  |
238 KB | Figure 2. Conceptual diagram of MC releases from a breached underwater UXO | 1 |
| 19:57, 23 March 2020 | Lotufo1w2Fig1.png (file) |  |
659 KB | Figure 1. Underwater munitions are derived from UXO and histrocial disposal practices. | 1 |
| 20:01, 19 March 2020 | 2016-Belden-Optimization of Integrative Passive Sampling Approaches-ER-2542.pdf (file) | |
1.08 MB | Belden J.B., Sims P., Rosen R., George R., Lotufo G.R., 2016. Optimization of Integrative Passive Sampling Approaches for Use in the Epibenthic Environment. Final Report. SERDP Project ER-2542 | 1 |
| 19:55, 19 March 2020 | 2015-Miege-Position Paper on Passive Sampling Techniques.pdf (file) | |
1.27 MB | Position paper on passive sampling techniques for the monitoring of contaminants in the aquatic environment - Achievements to date and perspectives. Trends in Environmental Analytical Chemistry, 8, pp.20-26 | 1 |
| 19:44, 19 March 2020 | 2016-Roll-Critical Review of Factors Governing Data Quality.pdf (file) | |
833 KB | Critical review of factors governing data quality of integrative samplers employed in environmental water monitoring. Water Research, 94, pp.200-207. DOI:10.1016/j.watres.2016.02.048 | 1 |
| 19:39, 19 March 2020 | 2017-Rosen-Validation of Passive Sampling Devices for Monitoring ER-201433.pdf (file) | |
9.26 MB | Rosen, G., Colvin, M., George, R. D., Lotufo, G. R., Woodley, C. M., Smith, D. L., and Belden, J. B., 2017. Validation of passive sampling devices for monitoring of munitions constituents in underwater environments, Technical Report 3076. Environmental... | 1 |
| 19:36, 19 March 2020 | 2019-Tobias-Tracking the Uptake, Translocation, Cycling and Metabolism-ER-2122.pdf (file) | |
7.01 MB | Tobias, C. 2019. Tracking the Uptake, Translocation, Cycling, and Metabolism of Munitions Compounds in Coastal Marine Ecosystems Using Stable Isotopic Tracer, Final report. SERDP Project ER-2122 | 1 |
| 19:33, 19 March 2020 | 2017-Lotufo-Review and Synthesis of Evidence Re Envl Risks.pdf (file) | |
13 MB | Lotufo, G.R., Chappell, M.A., Price, C.L., Ballentine, M.L., Fuentes, A.A., Bridges, T.S., George, R.D., Glisch, E.J., Carton, G. 2017. Review and Synthesis of Evidence Regarding Environmental Risks Posed by Munitions Constituents (MC) in Aquatic Syste... | 1 |
| 18:59, 19 March 2020 | 2018-Beck-Spread, Behavior and Ecosystem Consequences.pdf (file) | |
2.32 MB | Beck, A.J., Gledhill, M., Schlosser, C., Stamer, B., Böttcher, C., Sternheim, J., Greinert, J., Achterberg, E.P. 2018. Spread, behavior, and ecosystem consequences of conventional munitions compounds in coastal marine waters. Frontiers in Marine Scien... | 1 |
| 19:40, 17 March 2020 | 2013-Wang Defining Munition Constituent ER-1453.pdf (file) | |
4.24 MB | Wang, P. F., George, R. D., Wild, W. J., and Liao, Q., 2013. Defining munition constituent (MC) source terms in aquatic environments on DoD Ranges (ER-1453), Final Report. SSC Pacific Technical Report 1999. Strategic Environmental Research and Developm... | 1 |
| 19:34, 17 March 2020 | 2013-Lotufo-Summary Review of the Aqatic Toxicology.pdf (file) | |
4.14 MB | Summary Review of the Aquatic Toxicology of Munitions Constituents. ERDC Technical Report | 1 |
| 19:31, 17 March 2020 | 2012-Morin-Chemical Calibration Performance, Validation, and applications...POCIS.pdf (file) | |
537 KB | Morin, N., Miege, C., Randon, J., Coquery, M., 2012. Chemical calibration, performance, validation and applications of the polar organic chemical integrative sampler (POCIS) in aquatic environments | 1 |
| 19:29, 17 March 2020 | 2012-Harman-Calibration and use of the Polar Organic Chemical.pdf (file) | |
200 KB | Calibration and use of the polar organic chemical integrative sampler-a critical review | 1 |
| 19:25, 17 March 2020 | 2010-Rosen-Fate and effects of Composition B.pdf (file) | |
152 KB | Rosen, G., Lotufo, G.R., 2010. Fate and effects of Composition B in multispecies marine exposures. Environmental Toxicology and Chemistry, 29(6), pp.1330-1337 | 1 |
| 19:23, 17 March 2020 | 2001-Rodacy-Chemical Sensing of Explosive Targets in the Bedford basin.pdf (file) | |
1.48 MB | Rodacy, P. J., Reber, S. D., Walker, P. K., and Andre, J. V., 2001. Chemical sensing of explosive targets in the Bedford Basin, Halifax Nova Scotia. Sandia National Laboratories Report SAND2001-3569. | 1 |
| 14:33, 2 March 2020 | Ghosh2w2Fig3.png (file) |  |
927 KB | Figure 3. Telebelt conveyor spreading AC in a pelletized form (SediMite™) across Mirror Lake, DE. | 1 |
| 14:27, 2 March 2020 | Ghosh2w2Fig2.PNG (file) |  |
343 KB | Ghosh. Figure 2a, 2b, and 2c | 1 |
| 14:21, 2 March 2020 | Ghosh2w2Fig1.png (file) |  |
92 KB | Figure 1. Use of activated carbon in an active cap (left) and incorporation into surficial bioactive zone (right). | 1 |
| 20:21, 28 February 2020 | 2000-Ghosh-Microscale Location, Characterization, and Association of Polycyclic Aromatic Hydrocarbons.pdf (file) | |
469 KB | Ghosh, U.; Luthy, R.G.; Gillette, J.S.; Zare, R.N., 2000. Microscale Location, Characterization, and Association of Polycyclic Aromatic Hydrocarbons on Harbor Sediment Particles. Environmental Science and Technology, 34(9), pp. 1729-1736 | 1 |
| 15:51, 28 February 2020 | 2020-SERDP-In-place Remediation Technologies for Contaminated Sediments.pdf (file) | |
139 KB | Strategic Environmental Research and Development Program and Environmental Security Technology Certification Program (SERDP/ESTCP), no date. In-place Remediation Technologies for Contaminated Sediments. | 1 |
| 17:17, 27 February 2020 | 2014-ITRC-Contaminated Sediments Remediation.pdf (file) | |
5.14 MB | Interstate Technology & Regulatory Council (ITRC), 2014. Contaminated Sediments Remediation: Remedy Selection for Contaminated Sediments (CS-2). http://www.itrcweb.org/contseds_remedy-selection/ | 1 |
| 21:40, 26 February 2020 | 2017-Vlassopoulos-Evaluation Design and Construction.pdf (file) | |
6.56 MB | Vlassopoulos, D.; Russell, K.; Larosa, P.; Brown, R.; Mohan, R.; Glaza, E.; Drachenberg, T.; Reible, D.; Hague, W.; McAuliffe, J.; Miller, S., 2017. Evaluation, Design, and Construction of Amended Reactive Caps to Restore Onondaga Lake, Syracuse, New Y... | 1 |
| 21:37, 26 February 2020 | 2015-Patmont-In Situ Sediment Treatment.pdf (file) | |
1,011 KB | Patmont, C.R.; Ghosh, U.; LaRosa, P.; Menzie, C.A.; Luthy, R.G.; Greenberg, M.S.; Cornelissen, G.; Eek, E.; Collins, J.; Hull, J.; Hjartland, T.; Glaza, E.; Bleiler, J.; Quadrini. J., 2015. In Situ Sediment Treatment Using Activated Carbon: A Demonstra... | 1 |
| 21:35, 26 February 2020 | 2015-Bridges 2015- long-term Stability and Efficacy-ER-201580.pdf (file) | |
137 KB | Bridges, T., 2015. Long-Term Stability and Efficacy of Historic Activated Carbon (AC) Deployments at Diverse Freshwater and Marine Remediation Sites. Environmental Security Technology Certification Program (ESTCP), Alexandria, VA. Project number ER-201... | 1 |
| 21:32, 26 February 2020 | 2013-USEPA-Use of Amendments.pdf (file) | |
598 KB | U.S. Environmental Protection Agency (US EPA), 2013. Use of Amendments for In Situ Remediation at Superfund Sediment Sites. Office of Superfund Remediation and Technology Innovation. OSWER Directive 9200.2-128FS. | 1 |
| 21:22, 26 February 2020 | 2013-Janssen and Beckingham - Biological Responses to Activated Carbon Amendments.pdf (file) | |
1.02 MB | Janssen, E.M.L., and Beckingham, B.A., 2013. Biological Responses to Activated Carbon Amendments in Sediment Remediation. Environmental Science and Technology, 47(14), pp. 7595-7607. | 1 |
| 21:19, 26 February 2020 | 2005-USEPA-Contaminated Sediment Remediation Guidance.pdf (file) | |
2.82 MB | U.S. Environmental Protection Agency (US EPA), 2005. Contaminated Sediment Remediation Guidance for Hazardous Waste Sites. EPA-540-R-05-012. OSWER 9355.0-85 | 1 |
| 21:15, 26 February 2020 | 1997-Polayes- Habitat Considerations.pdf (file) | |
1.9 MB | Polayes, J., 1997. Habitat Considerations for large-Scale Sediment Capping Projects. Issue Paper, Washington State Department of Ecology | 1 |
| 20:09, 4 February 2020 | Kirkman1w2Fig5.png (file) |  |
118 KB | Figure 5. Residual LNAPL Saturation, Snr, as a function of the Initial LNAPL Saturation, S<sub>ni</sub>, for samples from three sites | 1 |
| 20:09, 4 February 2020 | Kirkman1w2Fig4.png (file) |  |
53 KB | Figure 4. Gauged LNAPL thickness versus potentiometric surface elevation through time showing 10 years of LNAPL recovery with little to no change in LNAPL thickness. | 1 |
| 20:08, 4 February 2020 | Kirkman1w2Fig3.png (file) |  |
116 KB | Figure 3. Aquifer transmissivity versus hydraulic conductivity | 1 |
| 20:04, 4 February 2020 | Kirkman1w2Fig2.png (file) |  |
86 KB | Figure 2. Hypothetical relative permeability curves for water and an LNAPL in a porous medium | 1 |
| 20:03, 4 February 2020 | Kirkman1w2Fig1.png (file) |  |
487 KB | Figure 1. LNAPL Distribution in a research sand tank | 1 |
