Journal
COLLOIDS AND SURFACES A-PHYSICOCHEMICAL AND ENGINEERING ASPECTS
Volume 613, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.colsurfa.2020.126097
Keywords
Superhydrophilicity; Enhanced green fluorescent protein; Graphene oxide; Humidity; Evaporation
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Superhydrophilic surfaces made by depositing graphene oxide on PVC substrates show zero contact angle initially but develop a contact angle over time. The spreading main contact line of EGFP drops is more easily visible under normal lighting conditions compared to blue LED lighting.
The use of superhydrophilic surfaces for superwetting applications can be hampered by their wetting degradation over time. In this work, superhydrophilic surfaces were fabricated by graphene oxide (GO) deposition on roughened polyvinyl chloride (PVC) substrates. These surfaces were found to exhibit zero contact angle when enhanced green fluorescent protein (EGFP) was deposited on the surface immediately after GO was applied. However, when the GO-coated substrate was stored for 3 h, the surface displayed a contact angle of 54.. The main contact line spreading of the EGFP drop was more easily discernible using normal (500 lx, low glare and shadow free) lighting than with blue LED lighting in the dark. The average radius of the spreading main contact line was found to follow a power-law relationship that increased at a faster rate with higher relative humidity. Confocal imaging revealed rings of EGFP deposition following superwetting that is attributable to pinning around the islands of GO accumulation. Substrate superhydrophilic and superwetting properties can be preserved by adequate control of relative humidity. Relative humidity of 80 % was easily maintained for 150 min by incorporating a 20 mu L water drop in a sealed 240-mL container.
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