Person:
Mulholland,
James A.
Mulholland,
James A.
Permanent Link
Associated Organization(s)
Organizational Unit
ORCID
ArchiveSpace Name Record
Publication Search Results
Now showing
1 - 10 of 10
-
ItemComparison of alternative exposure metrics of air pollution for use in public health surveillance(Georgia Institute of Technology, 2011-09-09) Mulholland, James A. ; Russell, Armistead G. ; Hu, Yongtau
-
ItemDevelopment in Real Time Detection of Trace Organics(Georgia Institute of Technology, 2008-01-25) Mulholland, James A.
-
ItemAnalysis of Temporal and Spatial Variations in Atlanta Air Quality For(Georgia Institute of Technology, 2005-02) Mulholland, James A. ; Marmur, Amit ; Wade, Katie ; Russell, Ted
-
ItemPolycyclic Aromatic Hydrocarbon Growth Mechanisms in Combustion Involving Cyclopentadiene and Indene(Georgia Institute of Technology, 2005) Mulholland, James A.
-
ItemStudy of air quality and health in Atlanta(Georgia Institute of Technology, 2004) Mulholland, James A.
-
ItemAir pollution and health in Atlanta(Georgia Institute of Technology, 2004) Mulholland, James A.
-
ItemDevelopment of jet REMPI as a research tool for toxic combustion byproduct measurement: research proposal planning activities(Georgia Institute of Technology, 2004) Mulholland, James A. ; Ryu, Jae-Yong ; Oh, Jeong-Eun
-
ItemLaboratory Study on the Transformation of Trichloroethylene under Thermal Source Zone Removal Conditions(Georgia Institute of Technology, 2003-04) Costanza, Jed ; Pennell, Kurt D. ; Mulholland, James A.Removal of separate-phase organic liquids from the subsurface has been hypothesized to reduce the long-term contamination of ground-water resources. Thermal source zone treatment is one remedial method being used to recover organic liquids from the subsurface. In-situ oxidation of organic contaminants is thought to occur during thermal treatment, resulting in the formation of benign reaction byproducts including carbon dioxide and water. This work presents the results from an ongoing laboratory investigation of the chemical transformation of trichloroethylene (TCE), a common source zone contaminant, as a function of temperature. The objective of this study is to quantify the TCE degradation products formed in a laboratory-scale reactor containing three phases (air, water, and solids) heated over a temperature range from 22 to 480°C to simulate subsurface conditions under thermal source zone treatment. Preliminary experimental results show that TCE reacts to form tetrachloroethylene (PCE), an unwanted byproduct, at temperatures greater than 300°C. Future experimental efforts will focus on the effect of granular medium and moisture content on chemical transformations.
-
ItemCharacterization Of Chlorinated Phenol Oxidation By Products Beyond Dioxin(Georgia Institute of Technology, 2002-12-31) Mulholland, James A.
-
ItemSophia Extend Air Quality Data Collection and Analysis(Georgia Institute of Technology, 2002-09-30) Mulholland, James A.