| 1 |
Humic acid and trihalomethane breakdown with potential by-product formations for atmospheric air plasma water treatment
Sarangapani C, Lu P, Behan P, Bourke P, Cullen PJ
Journal of Industrial and Engineering Chemistry, 59, 350, 2018 |
| 2 |
Efficacy and mechanistic insights into endocrine disruptor degradation using atmospheric air plasma
Sarangapani C, Danaher M, Tiwari B, Lu P, Bourke P, Cullen PJ
Chemical Engineering Journal, 326, 700, 2017 |
| 3 |
Microbial inactivation and pesticide removal by remote exposure of atmospheric air plasma in confined environments
Heo NS, Lee MK, Kim GW, Lee SJ, Park JY, Park TJ
Journal of Bioscience and Bioengineering, 117(1), 81, 2014 |
| 4 |
Effects of atmospheric air plasma treatment on interfacial properties of PBO fiber reinforced composites
Zhang CS, Li CY, Wang BY, Wang B, Cui H
Applied Surface Science, 276, 190, 2013 |
| 5 |
Characterization of nonwoven poly(ethylene terephtalate) devices functionalized with cationic polymer
Ran JH, Benistant G, Campagne C, Perichaud A, Chai F, Blanchemain N, Perwuelz A
Journal of Applied Polymer Science, 124(5), 3583, 2012 |
| 6 |
Forced Air Plasma Treatment (FAPT) of Hybrid Wood Plastic Composite (WPC)-Fiber Reinforced Plastic (FRP) Surfaces
Oporto GS, Gardner DJ, Bernhardt G, Neivandt DJ
Composite Interfaces, 16(7-9), 847, 2009 |
| 7 |
Studies on the Atmospheric Air-Plasma Treatment of PET (Polyethylene Terephtalate) Woven Fabrics: Effect of Process Parameters and of Aging
Takke V, Behary N, Perwuelz A, Campagne C
Journal of Applied Polymer Science, 114(1), 348, 2009 |
