 | Laboratory Studies (1.1.1) |
| Early Proof-of-Concept in the Field (1.1.2) |
| Early Commercial Use in Single Wells - (16 site study) (1.1.3) |
| Cost Comparison–Mechanical Treatment Methods (1.2.1) |
| Reducing O&M Costs by Monitoring Well Conversion (1.2.2) |
| Environmentally Safe (1.3.1) |
| pH Levels (1.3.2) |
| Disposal Issues (1.3.3) |
| Basic Theory on the Disposition of Compounds (1.3.4) |
| Field Results on the Disposition of Compounds (1.3.5) |
| Source Treatment Applications–Saturated Zone (2.1.1) |
| Source Treatment Applications–Tank Excavation (2.1.2) |
| Uses in Chlorinated Co-Metabolism (2.2.2.1) |
| Uses in Dual Phase Remediation of Chlorinated Hydrocarbons (2.2.2.2) |
| Remediation of Vinyl Chloride (2.2.2.3) |
| Remediation of Pentachlorophenol (2.2.2.4) |
| Vinyl Chloride Remediation Field Study (2.2.2.5) |
| Bioremediation of Nitrochlorobenzene, Nitroaniline, Chloroaniline in Groundwater (2.2.2.6) |
| ORC Injection Residential Petroleum Remediation in New Jersey (2.2.2.7) |
| ORC Injection Vinyl Chloride Remediation (2.2.2.8) |
| Potential for the Bioremediation of Methyl Tertiary Butyl Ether (MTBE) (2.2.3.1) |
| Does Competitive Inhibition Play a Role in MTBE Bioremediation? (2.2.3.2) |
| Uses in Biopiles (2.3.1) |
| Quantitative Guidelines for Soil Remediation Applications (Biopiles) (2.3.2) |
| Study with Dow Chemical on Soil Remediation Applications (Biopiles) (2.3.3) |
| Use in Existing Monitoring Wells (2.3.4) |
| Uses in Odor Control (2.3.5) |
| Iron Fouling (2.4.1.1) |
| Microbial Fouling (2.4.2.1) |
| Microbial Enhancement of Aquifer Populations (2.4.2.2) |
| Compatibility with Underground Tanks and Pipes (2.4.3.1) |
| Performance in Regions of Higher Salinity (2.4.3.2) |
| Oxygen Distribution in an Aquifer (2.5.1) |
| Oxygen Distribution Field Results–Alaska (2.5.2) |
| Computer Modeling Results for a Full Cut-off Barrier (2.5.3) |
| Computer Modeling Results for an Iterative Cut-off Design (2.5.4) |
