Investigating the interface of superhydrophobic surfaces in contact with water

Dhaval A. Doshi; Pratik B. Shah; Seema Singh; Eric D. Branson; Anthony P. Malanoski; Erik B. Watkins; Jaroslaw Majewski; Frank Van Swol; C. Jeffrey Brinker

doi:10.1021/la050750s

Investigating the interface of superhydrophobic surfaces in contact with water

Dhaval A. Doshi
, Pratik B. Shah
, Seema Singh
, Eric D. Branson
, Anthony P. Malanoski
, Erik B. Watkins
, Jaroslaw Majewski
, Frank Van Swol
, C. Jeffrey Brinker

Research output: Contribution to journal › Article › peer-review

61 Scopus citations

Abstract

Neutron reflectivity (NR) is used to probe the solid, liquid, vapor interface of a porous superhydrophobic (SH) surface submerged in water. A low-temperature, low-pressure technique was used to prepare a rough, highly porous organosilica aerogel-like film. UV/ozone treatments were used to control the surface coverage of hydrophobic organic ligands on the silica framework, allowing the contact angle with water to be continuously varied over the range of 160° (superhydrophobic) to < 10° (hydrophilic). NR shows that the superhydrophobic nature of the surface prevents infiltration of water into the porous film. Atomic force microscopy and density functional theory simulations are used in combination to interpret the NR results and help establish the location, width, and nature of the SH film-water interface.

Original language	English
Pages (from-to)	7805-7811
Number of pages	7
Journal	Langmuir
Volume	21
Issue number	17
DOIs	https://doi.org/10.1021/la050750s
State	Published - Aug 16 2005
Externally published	Yes

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10.1021/la050750s

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title = "Investigating the interface of superhydrophobic surfaces in contact with water",

abstract = "Neutron reflectivity (NR) is used to probe the solid, liquid, vapor interface of a porous superhydrophobic (SH) surface submerged in water. A low-temperature, low-pressure technique was used to prepare a rough, highly porous organosilica aerogel-like film. UV/ozone treatments were used to control the surface coverage of hydrophobic organic ligands on the silica framework, allowing the contact angle with water to be continuously varied over the range of 160° (superhydrophobic) to < 10° (hydrophilic). NR shows that the superhydrophobic nature of the surface prevents infiltration of water into the porous film. Atomic force microscopy and density functional theory simulations are used in combination to interpret the NR results and help establish the location, width, and nature of the SH film-water interface.",

author = "Doshi, \{Dhaval A.\} and Shah, \{Pratik B.\} and Seema Singh and Branson, \{Eric D.\} and Malanoski, \{Anthony P.\} and Watkins, \{Erik B.\} and Jaroslaw Majewski and \{Van Swol\}, Frank and Brinker, \{C. Jeffrey\}",

year = "2005",

month = aug,

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doi = "10.1021/la050750s",

language = "English",

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T1 - Investigating the interface of superhydrophobic surfaces in contact with water

AU - Doshi, Dhaval A.

AU - Shah, Pratik B.

AU - Singh, Seema

AU - Branson, Eric D.

AU - Malanoski, Anthony P.

AU - Watkins, Erik B.

AU - Majewski, Jaroslaw

AU - Van Swol, Frank

AU - Brinker, C. Jeffrey

PY - 2005/8/16

Y1 - 2005/8/16

N2 - Neutron reflectivity (NR) is used to probe the solid, liquid, vapor interface of a porous superhydrophobic (SH) surface submerged in water. A low-temperature, low-pressure technique was used to prepare a rough, highly porous organosilica aerogel-like film. UV/ozone treatments were used to control the surface coverage of hydrophobic organic ligands on the silica framework, allowing the contact angle with water to be continuously varied over the range of 160° (superhydrophobic) to < 10° (hydrophilic). NR shows that the superhydrophobic nature of the surface prevents infiltration of water into the porous film. Atomic force microscopy and density functional theory simulations are used in combination to interpret the NR results and help establish the location, width, and nature of the SH film-water interface.

AB - Neutron reflectivity (NR) is used to probe the solid, liquid, vapor interface of a porous superhydrophobic (SH) surface submerged in water. A low-temperature, low-pressure technique was used to prepare a rough, highly porous organosilica aerogel-like film. UV/ozone treatments were used to control the surface coverage of hydrophobic organic ligands on the silica framework, allowing the contact angle with water to be continuously varied over the range of 160° (superhydrophobic) to < 10° (hydrophilic). NR shows that the superhydrophobic nature of the surface prevents infiltration of water into the porous film. Atomic force microscopy and density functional theory simulations are used in combination to interpret the NR results and help establish the location, width, and nature of the SH film-water interface.

UR - https://www.scopus.com/pages/publications/33746680795

U2 - 10.1021/la050750s

DO - 10.1021/la050750s

M3 - Article

AN - SCOPUS:33746680795

SN - 0743-7463

VL - 21

SP - 7805

EP - 7811

JO - Langmuir

JF - Langmuir

IS - 17

ER -

Investigating the interface of superhydrophobic surfaces in contact with water

Abstract

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