Your search keyword '"Wickersham, Lindsay C."' showing total 5 results

1. Characterization of PFAS Air Emissions from Thermal Application of Fluoropolymer Dispersions on Fabrics

Author

Wickersham, Lindsay C., primary, Mattila, James M., additional, Krug, Jonathan D., additional, Jackson, Stephen R., additional, Wallace, M. Ariel Geer, additional, Shields, Erin P., additional, Halliday, Hannah, additional, Li, Emily Y., additional, Liberatore, Hannah K., additional, Farrior, Stanley (Mac), additional, Preston, William, additional, Ryan, Jeffrey V., additional, Lee, Chun-Wai, additional, and Linak, William P., additional

Published

2023

2. Combustion of C1 and C2 PFAS: Kinetic modeling and experiments

Author

Krug, Jonathan D., primary, Lemieux, Paul M., additional, Lee, Chun-Wai, additional, Ryan, Jeffrey V., additional, Kariher, Peter H., additional, Shields, Erin P., additional, Wickersham, Lindsay C., additional, Denison, Martin K., additional, Davis, Kevin A., additional, Swensen, David A., additional, Burnette, R. Preston, additional, Wendt, Jost O.L., additional, and Linak, William P., additional

Published

2022

3. Combustion of C1 and C2 PFAS: Kinetic modeling and experiments.

Author

Krug, Jonathan D., Lemieux, Paul M., Lee, Chun-Wai, Ryan, Jeffrey V., Kariher, Peter H., Shields, Erin P., Wickersham, Lindsay C., Denison, Martin K., Davis, Kevin A., Swensen, David A., Burnette, R. Preston, Wendt, Jost O.L., and Linak, William P.

Subjects

COMBUSTION kinetics, FLUOROALKYL compounds, ORGANIC wastes, TUBULAR reactors, CHEMICAL warfare agents, FOURIER transform infrared spectroscopy, COMBUSTION

Abstract

A combustion model, originally developed to simulate the destruction of chemical warfare agents, was modified to include C1-C3 fluorinated organic reactions and kinetics compiled by the National Institute of Standards and Technology (NIST). A simplified plug flow reactor version of this model was used to predict the destruction efficiency (DE) and formation of products of incomplete combustion (PICs) for three C1 and C2 per- and poly-fluorinated alkyl substances (PFAS) (CF4, CHF3, and C2F6) and compare predicted values to Fourier Transform Infrared spectroscopy (FTIR)-based measurements made from a pilot-scale EPA research combustor (40–64 kW, natural gas-fired, 20% excess air). PFAS were introduced through the flame, and at post-flame locations along a time-temperature profile allowing for simulation of direct flame and non-flame injection, and examination of the sensitivity of PFAS destruction on temperature and free radical flame chemistry. Results indicate that CF4 is particularly difficult to destroy with DEs ranging from ~60 to 95% when introduced through the flame at increasing furnace loads. Due to the presence of lower energy C-H and C-C bonds to initiate molecular dissociation reactions, CHF3 and C2F6 were easier to destroy, exhibiting DEs >99% even when introduced post-flame. However, these lower bond energies may also lead to the formation of CF2 and CF3 radicals at thermal conditions unable to fully de-fluorinate these species and formation of fluorinated PICs. DEs determined by the model agreed well with the measurements for CHF3 and C2F6 but overpredicted DEs at high temperatures and underpredicted DEs at low temperatures for CF4. However, high DEs do not necessarily mean absence of PICs, with both model predictions and limited FTIR measurements indicating the presence of similar fluorinated PICs in the combustion emissions. The FTIR was able to provide real-time emission measurements and additional model development may improve prediction of PFAS destruction and PIC formation. Implications: The widespread use of PFAS for over 70 years has led to their presence in multiple environmental matrixes including human tissues. While the chemical and thermal stability of PFAS are related to their desirable properties, this stability means that PFAS are very slow to degrade naturally and potentially difficult to destroy completely through thermal treatment processes often used for organic waste destruction. In this applied combustion study, model PFAS compounds were introduced to a pilot-scale EPA research furnace. Real-time FTIR measurements were performed of the injected compound and trace products of incomplete combustion (PICs) at operationally relevant conditions, and the results were successfully compared to kinetic model predictions of those same PFAS destruction efficiencies and trace gas-phase PIC constituents. This study represents a significant potential enhancement in available tools to support effective management of PFAS-containing wastes. [ABSTRACT FROM AUTHOR]

Published

2022

4. Combustion of C1and C2PFAS: Kinetic modeling and experiments

Author

Krug, Jonathan D., Lemieux, Paul M., Lee, Chun-Wai, Ryan, Jeffrey V., Kariher, Peter H., Shields, Erin P., Wickersham, Lindsay C., Denison, Martin K., Davis, Kevin A., Swensen, David A., Burnette, R. Preston, Wendt, Jost O.L., and Linak, William P.

Abstract

ABSTRACTA combustion model, originally developed to simulate the destruction of chemical warfare agents, was modified to include C1-C3fluorinated organic reactions and kinetics compiled by the National Institute of Standards and Technology (NIST). A simplified plug flow reactor version of this model was used to predict the destruction efficiency (DE) and formation of products of incomplete combustion (PICs) for three C1and C2per- and poly-fluorinated alkyl substances (PFAS) (CF4, CHF3, and C2F6) and compare predicted values to Fourier Transform Infrared spectroscopy (FTIR)-based measurements made from a pilot-scale EPA research combustor (40–64 kW, natural gas-fired, 20% excess air). PFAS were introduced through the flame, and at post-flame locations along a time-temperature profile allowing for simulation of direct flame and non-flame injection, and examination of the sensitivity of PFAS destruction on temperature and free radical flame chemistry. Results indicate that CF4is particularly difficult to destroy with DEs ranging from ~60 to 95% when introduced through the flame at increasing furnace loads. Due to the presence of lower energy C-H and C-C bonds to initiate molecular dissociation reactions, CHF3and C2F6were easier to destroy, exhibiting DEs >99% even when introduced post-flame. However, these lower bond energies may also lead to the formation of CF2and CF3radicals at thermal conditions unable to fully de-fluorinate these species and formation of fluorinated PICs. DEs determined by the model agreed well with the measurements for CHF3and C2F6but overpredicted DEs at high temperatures and underpredicted DEs at low temperatures for CF4. However, high DEs do not necessarily mean absence of PICs, with both model predictions and limited FTIR measurements indicating the presence of similar fluorinated PICs in the combustion emissions. The FTIR was able to provide real-time emission measurements and additional model development may improve prediction of PFAS destruction and PIC formation.Implications:The widespread use of PFAS for over 70 years has led to their presence in multiple environmental matrixes including human tissues. While the chemical and thermal stability of PFAS are related to their desirable properties, this stability means that PFAS are very slow to degrade naturally and potentially difficult to destroy completely through thermal treatment processes often used for organic waste destruction. In this applied combustion study, model PFAS compounds were introduced to a pilot-scale EPA research furnace. Real-time FTIR measurements were performed of the injected compound and trace products of incomplete combustion (PICs) at operationally relevant conditions, and the results were successfully compared to kinetic model predictions of those same PFAS destruction efficiencies and trace gas-phase PIC constituents. This study represents a significant potential enhancement in available tools to support effective management of PFAS-containing wastes.

Published

2022

5. Combustion of C 1 and C 2 PFAS: Kinetic modeling and experiments.

Author

Krug JD, Lemieux PM, Lee CW, Ryan JV, Kariher PH, Shields EP, Wickersham LC, Denison MK, Davis KA, Swensen DA, Burnette RP, Wendt JOL, and Linak WP

Subjects

Humans, Kinetics, Temperature, Fluorocarbons analysis, Incineration methods

Abstract

A combustion model, originally developed to simulate the destruction of chemical warfare agents, was modified to include C 1 -C 3 fluorinated organic reactions and kinetics compiled by the National Institute of Standards and Technology (NIST). A simplified plug flow reactor version of this model was used to predict the destruction efficiency (DE) and formation of products of incomplete combustion (PICs) for three C 1 and C 2 per- and poly-fluorinated alkyl substances (PFAS) (CF 4 , CHF 3 , and C 2 F 6 ) and compare predicted values to Fourier Transform Infrared spectroscopy (FTIR)-based measurements made from a pilot-scale EPA research combustor (40-64 kW, natural gas-fired, 20% excess air). PFAS were introduced through the flame, and at post-flame locations along a time-temperature profile allowing for simulation of direct flame and non-flame injection, and examination of the sensitivity of PFAS destruction on temperature and free radical flame chemistry. Results indicate that CF 4 is particularly difficult to destroy with DEs ranging from ~60 to 95% when introduced through the flame at increasing furnace loads. Due to the presence of lower energy C-H and C-C bonds to initiate molecular dissociation reactions, CHF 3 and C 2 F 6 were easier to destroy, exhibiting DEs >99% even when introduced post-flame. However, these lower bond energies may also lead to the formation of CF 2 and CF 3 radicals at thermal conditions unable to fully de-fluorinate these species and formation of fluorinated PICs. DEs determined by the model agreed well with the measurements for CHF 3 and C 2 F 6 but overpredicted DEs at high temperatures and underpredicted DEs at low temperatures for CF 4 . However, high DEs do not necessarily mean absence of PICs, with both model predictions and limited FTIR measurements indicating the presence of similar fluorinated PICs in the combustion emissions. The FTIR was able to provide real-time emission measurements and additional model development may improve prediction of PFAS destruction and PIC formation. Implications: The widespread use of PFAS for over 70 years has led to their presence in multiple environmental matrixes including human tissues. While the chemical and thermal stability of PFAS are related to their desirable properties, this stability means that PFAS are very slow to degrade naturally and potentially difficult to destroy completely through thermal treatment processes often used for organic waste destruction. In this applied combustion study, model PFAS compounds were introduced to a pilot-scale EPA research furnace. Real-time FTIR measurements were performed of the injected compound and trace products of incomplete combustion (PICs) at operationally relevant conditions, and the results were successfully compared to kinetic model predictions of those same PFAS destruction efficiencies and trace gas-phase PIC constituents. This study represents a significant potential enhancement in available tools to support effective management of PFAS-containing wastes.

Published

2022