File list
This special page shows all uploaded files.
| Date | Name | Thumbnail | Size | Description | Versions |
|---|---|---|---|---|---|
| 18:04, 5 March 2019 | Liu1w2 Eq2.png (file) |  |
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| 18:03, 5 March 2019 | Liu1w2 Eq1.png (file) |  |
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| 21:49, 18 February 2019 | Allen-King1w2 Fig5.png (file) |  |
126 KB | 1 | |
| 21:48, 18 February 2019 | Allen-King1w2 Fig4.png (file) |  |
57 KB | 1 | |
| 21:48, 18 February 2019 | Allen-King1w2 Fig3.png (file) |  |
115 KB | 1 | |
| 21:47, 18 February 2019 | Allen-King1w2 Fig2.png (file) |  |
75 KB | 1 | |
| 21:46, 18 February 2019 | Allen-King1w2 Fig1b.png (file) |  |
453 KB | 1 | |
| 21:44, 18 February 2019 | Allen-King1w2 Fig1a.png (file) |  |
202 KB | Figure 1. Batch reactor experiments (a, top) to generate points on a sorption isotherm (b). Part (a) shows two samples prepared in duplicate with soil-free control vials and vials to verify the contaminant mass added to the systems. Part (b) shows lin... | 1 |
| 21:43, 18 February 2019 | Allen-King1w2 Eq6.png (file) |  |
5 KB | 1 | |
| 21:42, 18 February 2019 | Allen-King1w2 Eq5.png (file) |  |
8 KB | 1 | |
| 21:41, 18 February 2019 | Allen-King1w2 Eq4.png (file) |  |
6 KB | 1 | |
| 21:39, 18 February 2019 | Allen-King1w2 Eq3.png (file) |  |
18 KB | 1 | |
| 21:39, 18 February 2019 | Allen-King1w2 Eq2.png (file) |  |
6 KB | 1 | |
| 21:37, 18 February 2019 | Allen-King1w2 Eq1.png (file) |  |
5 KB | 1 | |
| 20:27, 18 February 2019 | 1990-Piwoni-Basic concepts sorption haz site EPA 540-4-90-053.pdf (file) |  |
45 KB | Piwoni, M.D., and Keeley, J.W., 1990. Basic Concepts of Contaminant Sorption at Hazardous Waste Sites. USEPA, Ground Water Issue, EPA/540/4-90/053. | 1 |
| 17:27, 11 February 2019 | Hatzinger1w2 Fig4.png (file) |  |
1,017 KB | Figure 4. Field-Scale In Situ Propane Biosparging System | 1 |
| 17:26, 11 February 2019 | Hatzinger1w2 Fig3.png (file) |  |
303 KB | Figure 3. Layout of biosparging system<ref name= "Hatzinger2015"/>. | 1 |
| 17:24, 11 February 2019 | Hatzinger1w2 Fig2.png (file) |  |
390 KB | Figure 2. Field-Scale Propane-Fed FBR | 1 |
| 17:23, 11 February 2019 | Hatzinger1w2 Fig1.png (file) |  |
19 KB | Figure 1. NDMA chemical structure | 1 |
| 15:04, 11 February 2019 | 2014-USEPA-N-Nitrosodimethylamine fact sheet.pdf (file) | |
118 KB | USEPA. 2014. Technical Fact Sheet - N-Nitroso-dimethylamine. USEPA Office of Solid Waste and Emergency Response. EPA 505-F-14-005. | 1 |
| 22:11, 8 February 2019 | 2015-Hatzinger-Field Demonstration of Propane Biosparging.pdf (file) | |
24.57 MB | Hatzinger, P.B., Lippincott, D., 2015. Field Demonstration of Propane Biosparging for In Situ Remediation of n-Nitrosodimethylamine (NDMA) in Groundwater. ESTCP Project ER-200828. | 1 |
| 16:32, 5 February 2019 | Craig1w2 Fig4.png (file) |  |
146 KB | Figure 4: Degradation kinetics of three munitions contaminants in two UMDA windrows (modified from: Weston, 1993 | 1 |
| 16:30, 5 February 2019 | Craig1w2 Fig3.png (file) |  |
650 KB | Figure 3: Windrow Turner at Plum Brook Ordinance Works | 1 |
| 16:29, 5 February 2019 | Craig1w2 Fig2.png (file) |  |
1.21 MB | Figure 2: Key steps of windrow composting process at UMDA including: excavation of contaminated soil to 15 feet below ground surface (left), loading windrow machine with soil and amendments (middle), and periodically turning the windrows (right). | 1 |
| 16:28, 5 February 2019 | Craig1w2 Fig1.png (file) |  |
38 KB | Figure 1: Compound reductions for different composting techniques using soils from contaminated ammunition production sites. Error bars are ± 1 standard deviation. IVSP = in-vessel static pile; MAIV = mechanically agitated in-vessel. Data compiled by... | 1 |
| 21:29, 1 February 2019 | 2002-EPA-Application, Performance, and Costs for Biotreatment Tech for Cont Soils.pdf (file) | |
2.09 MB | EPA (2002) Application, Performance, and Costs for Biotreatment Technologies for Contaminated Soils. | 1 |
| 21:27, 1 February 2019 | 1995-Craig-Bioremediation of explosives-Contaminated Soils.pdf (file) | |
530 KB | Craig, H.D., Sisk, W.E., Nelson, M.D. and W.H. Dana (1995) Bioremediation of Explosives-Contaminated Soils: A Status Review. Proceedings of the 10th Annual Conference on Hazardous Waste Research | 1 |
| 21:26, 1 February 2019 | 1993-AEC Technology Applicatons Analysis.pdf (file) | |
921 KB | AEC (1993) Technology Applications Analysis: Windrow Composting of Explosives Contaminated Soils at Umatilla Army Depot Activity | 1 |
| 21:25, 1 February 2019 | 1993-Weston-Windrow Composting Demo for Explosives.pdf (file) | |
11.69 MB | Weston (1993), Windrow Composting Demonstration for Explosives-Contaminated Soils at the Umatilla Depot Activity Hermiston, Oregon. U.S. Army Environmental Center Report No. CETHA-TS-CR-93043. | 1 |
| 21:23, 1 February 2019 | 1991-Weston-Optimization of Composting Explosives Contaminated soils.pdf (file) | |
6.83 MB | Weston (1991) Optimization of Composting Explosives Contaminated Soils at Umatilla, U.S. Army Toxic and Hazardous Materials Agency Report No. CETHA-TS-CR-91053. | 1 |
| 21:21, 1 February 2019 | 1988-Weston-field Demonstration - Composting Explosives at LAAP.pdf (file) | |
6.34 MB | Weston, R.F. (1988) Field Demonstration—Composting Explosives-Contaminated Sediments at the Louisiana Army Ammunition Plant (LAAP). | 1 |
| 21:02, 1 February 2019 | 1986-Doyle-Composting Explosives Organics Contaminated Soils.pdf (file) | |
6.92 MB | Doyle, R.C., Isbister, J.D., Anspach, G.L., and J.F. Kitchens (1986) Composting Explosives/Organics Contaminated Soils, Atlantic Research Corporation | 1 |
| 19:41, 1 February 2019 | 1982-Isbister-Engineering and development Support of general Decon Tech.pdf (file) | |
3.32 MB | Isbister, J.D., Doyle, R.C., and J.F. Kitchens (1982) Engineering and Development Support of General Decon Technology for the U.S. Army's Installation Restoration Program. Task 2 – Composting of Explosives, Atlantic Research Corporation | 1 |
| 17:27, 1 February 2019 | 2018-UFGS for Bioremediation of Soils using Windrow Composting.pdf (file) | |
216 KB | Unified Facilities Guide Specifications for Bioremediation of Soils using Windrow Composting | 1 |
| 15:05, 1 February 2019 | 2011-ACOE-pwtb 200 1 95.pdf (file) | |
1.06 MB | • ACOE (2011) Soil Composting for Explosives Remediation: Case Studies and Lessons Learned, U.S. Army Corps of Engineers, Public Works Technical Bulletin 200-1-95. | 1 |
| 20:08, 31 January 2019 | 1980- Somerton- Role of Clays in the enhanced reovery of petroleum.pdf (file) | |
1.08 MB | <ref>Somerton, W. H., and C. J. Radke. 1980. Roles of clays in the enhanced recovery of petroleum. Proceedings of the first joint SPE/DOE symposium on enhance oil recovery. Society of Petroleum Engineers.</ref> | 1 |
| 22:02, 30 January 2019 | Johnson1w2 Fig4.png (file) |  |
44 KB | Figure 4: General heuristics for determining application of alkaline amendments for the management of munitions constituents in soil. | 1 |
| 22:01, 30 January 2019 | Johnson1w2 Fig3.png (file) |  |
784 KB | Figure 3: Soil mixing during ex situ alkaline treatment of soils at an ammunition plant. | 1 |
| 22:01, 30 January 2019 | Johnson1w2 Fig2.png (file) |  |
32 KB | Figure 2: Mean pore water RDX concentrations by hand grenade bay and lysimeter with maximum and minimum concentration profiles (avg, n ranges from 7 to 10; modified from Larson et al., 2007). | 1 |
| 22:00, 30 January 2019 | Johnson1w2 Fig1.png (file) |  |
26 KB | Figure 1: RDX concentrations in leachate by rain event for meso-scale lysimeters containing hand grenade range soils as reported by Larson et al. (2007) | 1 |
| 21:29, 30 January 2019 | 2007-Santiago-chemical remediation of an ordnance related compound.pdf (file) | |
852 KB | Santiago, L., Felt, D.R. and Davis, J.L., 2007. Chemical Remediation of an Ordnance-Related Compound: The Alkaline Hydrolysis of CL-20. Environmental Quality Technology Program (No. ERDC/EL-TR-07-18). Engineer Research and Development Center, Vicksbu... | 1 |
| 20:35, 30 January 2019 | 2007-Larson-grenade Range Management Using Lime for Metals Immobilization.pdf (file) | |
2.2 MB | Larson, S.L., J.L. Davis, W.A. Martin, D.R. Felt, C.C. Nestler, D.L. Brandon, G. Fabian, and G. O’Connor. 2007. Grenade Range Management Using Lime for Metals Immobilization and Explosives Transformation: Treatability Study. ERDC/EL TR-07-5. Vicksbur... | 1 |
| 20:27, 30 January 2019 | 1998-Kim-Alkline Hydrolysis Biodegradation of Nitrocellulose Fines.pdf (file) | |
6.17 MB | Kim, B.J., Alleman, J.E. and Quivey, D.M., 1998. Alkaline hydrolysis/biodegradation of nitrocellulose fines (No. CERL-TR-98/65). Consstruction Engineering Researcg Lab (ARMY) Champaign, IL. | 1 |
| 21:04, 29 January 2019 | 2010-Gent-laboratory Demostration of abiotic tech for removal of RDX.pdf (file) | |
11.89 MB | Gent, D.B., Johnson, J.L., Felt, D.R., O'Connor, G., Holland, E., May, S. and Larson, S.L., 2010. Laboratory demonstration of abiotic technologies for removal of RDX from a process waste stream (No. ERDC/EL-TR-10-8). Engineer Research and Development... | 1 |
| 20:54, 29 January 2019 | 2001-Felt- Potential for biodegradatio of the alkaline hydrolysis.pdf (file) | |
3.97 MB | Potential for biodegradation of the alkaline hydrolysis end products of TNT and RDX. ERDC/EL TR-07-25. Vicksburg, MS: U.S. Army Engineer Research and Development Center | 1 |
| 19:43, 28 January 2019 | 2011 - Johnson - Management of Munitions Constituents in Soil.pdf (file) | |
886 KB | Management of Munitions Constituents in Soil Using Alkaline Hydrolysis | 1 |
| 19:33, 23 January 2019 | Wilkin1w2 Fig2.png (file) |  |
410 KB | Figure 2. False-color scanning electron micrograph | 1 |
| 19:33, 23 January 2019 | Wilkin1w2 Fig1.png (file) |  |
48 KB | Conceptual Model of PRB. Adapted from Wilkin, et al., 2002 | 1 |
| 21:22, 21 January 2019 | 2018-ESTCP Analysis of Long-Term performance of Zero-valent Iron App.pdf (file) | |
65.03 MB | 25. ESTCP, 2018. Analysis of Long-Term Performance of Zero-valent Iron Applications. Project Report #ER-201589-PR. | 1 |
| 15:55, 21 January 2019 | 2002-Wilkin-Long-term Perf of Permeable Reactive Barriers Using Zero-valent.pdf (file) | |
2.27 MB | 3. Wilkin, R.T., Puls, R.W., Sewell, G.W., 2002. Environmental Research Brief: Long-term Performance of Permeable Reactive Barriers Using Zero-valent Iron: An Evaluation at Two Sites. US EPA, Office of Research and Development, National Risk Management... | 1 |
