Loading...
Per- and polyfluoroalkyl substances (PFAS) and alternatives: structure, characterization, and degradation
Mifkovic, Maleigh
Mifkovic, Maleigh
Citations
Altmetric:
Advisor
Editor
Date
Date Issued
2023
Date Submitted
Collections
Files
Loading...
Mifkovic_mines_0052E_12565.pdf
Adobe PDF, 24.88 MB
Mifkovic_mines_0052E_316/Reprint Permission - Chapter 2 - Daniel Van Hoomissen.txt
Text, 785 B
Mifkovic_mines_0052E_316/Reprint Permission - Chapter 4 - Jessica Pauling.txt
Text, 892 B
Mifkovic_mines_0052E_316/Reprint Permission - Chapter 6 - Brian Etz.txt
Text, 875 B
Mifkovic_mines_0052E_316/Reprint Permission - Chapter 6 - Manoj Shukla.txt
Text, 1.34 KB
Research Projects
Organizational Units
Journal Issue
Embargo Expires
Abstract
Since their synthesis and commercialization over seven decades ago, per- and polyfluoroalkyl substances
(PFAS) have notoriously become known as worldwide contaminants due to their toxicity, persistence, and
bioaccumulation. Thus, it is paramount to accurately identify these compounds in environmental samples
for effective remediation, as well as implement alternatives which are less recalcitrant and toxic. The
resistance of PFAS degradation is a result of their chemical and thermal stability, which may be a result of
their unique helical conformations. To understand if PFAS robustness can be attributed to their structures,
the relationship between helicity and fundamental molecular properties of a class of four-carbon
polyfluoroalkanes is explored. Additionally, helicity is not significantly impacted by polar head groups but
is broken with radicals located towards the center of the molecule, which may have implications in
facilitating degradation. The functional diversity within the PFAS family also creates unique challenges in
identification and remediation. 19F NMR spectroscopy has recently become a suitable technique to
characterize PFAS in concentrated samples. Thus, this work first develops a computational protocol to
accurately predict chemical shifts (within 2-4 ppm) specifically for perfluoroalkanes. This method is further
applied to environmentally relevant short chain PFAS and shows that implicit solvation may be necessary
for accurate predictions. Trimethylsiloxane (TriSil) surfactants are a possible fluorine-free replacement to
PFAS as fire suppressants. To evaluate their environmental impact and support including TriSil in foam
formulations, potential degradation products of a truncated TriSil in high temperature and aqueous
(hydrolysis, reduction, and oxidation) conditions are determined. All degradation products are small
organics and PDMS-like products, which are relatively safer than those of PFAS. The work presented
herein uses density functional theory methods to study the structure of PFAS, its connection to properties,
characterization by 19F NMR, and additionally identify prominent degradation pathways and products of
TriSil.
Associated Publications
Rights
Copyright of the original work is retained by the author.