Wetting 101°

Langmuir

Volumn 25, Issue 24, 2009, Pages 14105-14115

  Gao, Lichao ^a   McCarthy, Thomas J ^a  

^a UNIVERSITY OF MASSACHUSETTS   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CONTACT ANGLE HYSTERESIS; CONTACT LINES; LOTUS EFFECT; SUPERHYDROPHOBICITY; SURFACE SCIENCE;

CONTACT ANGLE; HYDROPHOBICITY; TWO DIMENSIONAL;

WETTING;

EID: 74049162951     PISSN: 07437463     EISSN: None     Source Type: Journal    
DOI: 10.1021/la902206c     Document Type: Review

References (78)

1. References 2-6 are reviews of superhydophobicity.
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10. Young does not actually say that his premise is consistent with both theory and experiment but "equally with both." His essay certainly suggests his belief in this premise and that the wording is not meant as a qualification; however, this man's intelligence is daunting and can convince the reader to "read in between the lines" and even suppose divine powers.
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20. Figure 1 of ref 11 is a plot of citations versus year that shows the growth of superhydrophobicity.
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48. Gray, V. R. Chem. Ind. 1965, 23, 969. We cited this paper in ref 12. We should have cited it in ref 11 and a number of our other publications, but we were unaware of it. Prior to our citation, this forgotten work was previously cited in 1997 (once) and before that in 1986 (once).
49. 16,17 surfaces is an intuitively obvious way to picture surface free energy. The drop changes shape from a section of a sphere, increasing its surface area. Bulk molecules must move from the bulk to the surface, and work is required to do this. Figure 3 in ref 17 and Figure 3 in ref 18 show photographs of the compression of water drops using surfaces with 180° contact angles.
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