Photochemistry of iron complexes for water treatment. In Springer Handbook of Inorganic Photochemistry.. (2020).
Production of oxidizing intermediates during corrosion of iron; implications for remediation of contaminants from mineral and metal processing. In ECS Transactions (Vol. 28, pp. 117-127). doi:10.1149/1.3367907. (2010).
A Field-Validated Passive Sampler for the Monitoring of Per- and Polyfluoroalkyl Substances (PFAS) in Sediment Pore Water and Surface Water.. (Submitted).
The Effect of Polarity Reversal on Faradaic Efficiency, Precipitate Characteristics, and Contaminant Removal in Aluminum Electrocoagulation.. (Submitted).
Longevity of Colloidal Activated Carbon for In-Situ PFAS Remediation at AFFF-Contaminated Airport Sites. Remediation Journal.. (2022).
Evidence of Precipitate Formation and Byproduct Transfer to Non-Aqueous Phase Liquids as a Result of Persulfate Exposure. Remediation Journal, 32(3), 211-219.. (2022).
Treatment of Electrochemical Plating Wastewater by Heterogeneous Photocatalysis: The Simultaneous removal of 6:2 Fluorotelomer Sulfonate and Hexavalent Chromium. RSC Advances, (11), 37472 - 37481.. (2021).
How Does Periodic Polarity Reversal Affect the Faradaic Efficiency and Electrode Fouling during Iron Electrocoagulation?. Water Research, 203, 117497.. (2021).
Synergistic Effect Between the S-TiO2 photocatalyst and the Fenton-like System: Enhanced Contaminant Oxidation Under Visible Light Illumination. Journal of Environmental and Chemical Engineering, 104598.(2021).
Mitigating Electrode Scaling in Electrocoagulation by Means of Polarity Reversal: The Effects of Electrode Type, Current Density, and Polarity Reversal Frequency. Water Research, 117074.. (2021).
Activation of Hydrogen Peroxide by a Titanium Oxide-Supported Iron Catalyst: Evidence for Surface Fe(IV) and Its Selectivity. Environmental Science & Technology, 54(23), 15424-15432.(2020).
Treatment of sulfolane in groundwater: a critical review. Journal of Environmental Management, 110385.. (2020).
Nickel–Nickel Oxide Nanocomposite as a MagneticallySeparable Persulfate Activator for the Nonradical Oxidationof Organic Contaminants. Journal of Hazardous Materials, 121767.(2020).
Reduction of chlorendic acid by zero-valent iron: kinetics, products, and pathways. Journal of Hazardous Materials, 121269.. (2020).
In situ chemical oxidation of chlorendic acid by persulfate: Elucidation of the roles of adsorption and oxidation on chlorendic acid removal. Water Research, 162, 78-86. Retrieved from doi.org/10.1016/j.watres.2019.06.061. (2019).
Effective removal of silica and sulfide from oil sands thermal in-situproduced water by electrocoagulation. Journal of Hazardous Materials, 380, 120880.. (2019).
Evaluating the longevity of a PFAS in situ colloidal activated carbon remedy. Remediation Journal, 29, 17-31. doi:10.1002/rem.21593. (2019).
Oxidation of benzoic acid by heat-activated persulfate: Effect of temperature on transformation pathway and product distribution. Water Research, 120, 43-51. Elsevier Ltd. doi:10.1016/j.watres.2017.04.066. (2017).
Influence of Sulfide Nanoparticles on Dissolved Mercury and Zinc Quantification by Diffusive Gradient in Thin-Film Passive Samplers. Environmental Science & Technology, 49, 12897-12903. American Chemical Society. doi:10.1021/acs.est.5b02774. (2015).
Precipitation of nanoscale mercuric sulfides in the presence of natural organic matter: Structural properties, aggregation, and biotransformation. Geochimica et Cosmochimica Acta, 133, 204-215. Elsevier Ltd. doi:10.1016/j.gca.2014.02.027. (2014).