TY - JOUR
T1 - Sustaining dry surfaces under water
AU - Jones, Paul R.
AU - Hao, Xiuqing
AU - Cruz-Chu, Eduardo R.
AU - Rykaczewski, Konrad
AU - Nandy, Krishanu
AU - Schutzius, Thomas M.
AU - Varanasi, Kripa K.
AU - Megaridis, Constantine M.
AU - Walther, Jens H.
AU - Koumoutsakos, Petros
AU - Espinosa, Horacio D.
AU - Patankar, Neelesh A.
N1 - Funding Information: N.A.P., H.D.E. and K.N. acknowledge support from the Initiative for Sustainability and Energy at Northwestern (ISEN). X.H. acknowledges support from the Chinese Research Council. N.A.P. and P.R.J. acknowledge computing resources from Northwestern University’s high performance computing system (QUEST). K.R. acknowledges NIST for access to electron microscopy resources, and Dr. Albert Davydov and Dr. Sergiy Krylyuk from NIST for providing the VLS silicon nanowire samples.
PY - 2015/8/18
Y1 - 2015/8/18
N2 - Rough surfaces immersed under water remain practically dry if the liquid-solid contact is on roughness peaks, while the roughness valleys are filled with gas. Mechanisms that prevent water from invading the valleys are well studied. However, to remain practically dry under water, additional mechanisms need consideration. This is because trapped gas (e.g. air) in the roughness valleys can dissolve into the water pool, leading to invasion. Additionally, water vapor can also occupy the roughness valleys of immersed surfaces. If water vapor condenses, that too leads to invasion. These effects have not been investigated, and are critically important to maintain surfaces dry under water. In this work, we identify the critical roughness scale, below which it is possible to sustain the vapor phase of water and/or trapped gases in roughness valleys-thus keeping the immersed surface dry. Theoretical predictions are consistent with molecular dynamics simulations and experiments.
AB - Rough surfaces immersed under water remain practically dry if the liquid-solid contact is on roughness peaks, while the roughness valleys are filled with gas. Mechanisms that prevent water from invading the valleys are well studied. However, to remain practically dry under water, additional mechanisms need consideration. This is because trapped gas (e.g. air) in the roughness valleys can dissolve into the water pool, leading to invasion. Additionally, water vapor can also occupy the roughness valleys of immersed surfaces. If water vapor condenses, that too leads to invasion. These effects have not been investigated, and are critically important to maintain surfaces dry under water. In this work, we identify the critical roughness scale, below which it is possible to sustain the vapor phase of water and/or trapped gases in roughness valleys-thus keeping the immersed surface dry. Theoretical predictions are consistent with molecular dynamics simulations and experiments.
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U2 - 10.1038/srep12311
DO - 10.1038/srep12311
M3 - Article
SN - 2045-2322
VL - 5
JO - Scientific reports
JF - Scientific reports
M1 - 12311
ER -