From aggregative adsorption to surface depletion: aqueous systems of CnEm amphiphiles at hydrophilic surfaces

Gernot Rother; Dirk Müter; Henry Bock; Martin Schoen; Gerhard H. Findenegg

doi:10.1080/00268976.2017.1299234

From aggregative adsorption to surface depletion: aqueous systems of C_nE_m amphiphiles at hydrophilic surfaces

Gernot Rother, Dirk Müter, Henry Bock, Martin Schoen, Gerhard H. Findenegg^*

^*Corresponding author for this work

Department of Chemistry

3 Citations (Scopus)

Abstract

Adsorption of a short-chain nonionic amphiphile (C₆E₃) at the surface of mesoporous silica glass (CPG) was studied by a combination of adsorption measurements and mesoscale simulations. Adsorption measurements covering a wide composition range of the C₆E₃ + water system show that no adsorption occurs up to the critical micelle concentration, at which a sharp increase of adsorption is observed that is attributed to ad-micelle formation at the pore walls. Intriguingly, as the concentration is increased further, the surface excess of the amphiphile begins to decrease and eventually becomes negative, which corresponds to preferential adsorption of water rather than amphiphile at high amphiphile concentrations. The existence of such a surface-azeotropic point has not previously been reported in the surfactant adsorption field. Dissipative particle dynamics simulations were performed to reveal the structural origin of this transition from aggregative adsorption to surface depletion. The simulations indicate that this transition can be attributed to the repulsive interaction between head groups, causing depletion of the amphiphile in the region around the corona of the surface micelles.

Original language	English
Journal	Molecular Physics
Volume	115
Issue number	9-12
Pages (from-to)	1408-1416
Number of pages	9
ISSN	0026-8976
DOIs	https://doi.org/10.1080/00268976.2017.1299234
Publication status	Published - 18 Jun 2017

Keywords

Adsorption
mesoscale simulations
nanopores
surface azeotrope
surfactant

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10.1080/00268976.2017.1299234

Cite this

@article{535512b30f8946ef979be97c4b8ff007,

title = "From aggregative adsorption to surface depletion: aqueous systems of CnEm amphiphiles at hydrophilic surfaces",

abstract = "Adsorption of a short-chain nonionic amphiphile (C6E3) at the surface of mesoporous silica glass (CPG) was studied by a combination of adsorption measurements and mesoscale simulations. Adsorption measurements covering a wide composition range of the C6E3 + water system show that no adsorption occurs up to the critical micelle concentration, at which a sharp increase of adsorption is observed that is attributed to ad-micelle formation at the pore walls. Intriguingly, as the concentration is increased further, the surface excess of the amphiphile begins to decrease and eventually becomes negative, which corresponds to preferential adsorption of water rather than amphiphile at high amphiphile concentrations. The existence of such a surface-azeotropic point has not previously been reported in the surfactant adsorption field. Dissipative particle dynamics simulations were performed to reveal the structural origin of this transition from aggregative adsorption to surface depletion. The simulations indicate that this transition can be attributed to the repulsive interaction between head groups, causing depletion of the amphiphile in the region around the corona of the surface micelles.",

keywords = "Adsorption, mesoscale simulations, nanopores, surface azeotrope, surfactant",

author = "Gernot Rother and Dirk M{\"u}ter and Henry Bock and Martin Schoen and Findenegg, {Gerhard H.}",

year = "2017",

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doi = "10.1080/00268976.2017.1299234",

language = "English",

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TY - JOUR

T1 - From aggregative adsorption to surface depletion

T2 - aqueous systems of CnEm amphiphiles at hydrophilic surfaces

AU - Rother, Gernot

AU - Müter, Dirk

AU - Bock, Henry

AU - Schoen, Martin

AU - Findenegg, Gerhard H.

PY - 2017/6/18

Y1 - 2017/6/18

N2 - Adsorption of a short-chain nonionic amphiphile (C6E3) at the surface of mesoporous silica glass (CPG) was studied by a combination of adsorption measurements and mesoscale simulations. Adsorption measurements covering a wide composition range of the C6E3 + water system show that no adsorption occurs up to the critical micelle concentration, at which a sharp increase of adsorption is observed that is attributed to ad-micelle formation at the pore walls. Intriguingly, as the concentration is increased further, the surface excess of the amphiphile begins to decrease and eventually becomes negative, which corresponds to preferential adsorption of water rather than amphiphile at high amphiphile concentrations. The existence of such a surface-azeotropic point has not previously been reported in the surfactant adsorption field. Dissipative particle dynamics simulations were performed to reveal the structural origin of this transition from aggregative adsorption to surface depletion. The simulations indicate that this transition can be attributed to the repulsive interaction between head groups, causing depletion of the amphiphile in the region around the corona of the surface micelles.

AB - Adsorption of a short-chain nonionic amphiphile (C6E3) at the surface of mesoporous silica glass (CPG) was studied by a combination of adsorption measurements and mesoscale simulations. Adsorption measurements covering a wide composition range of the C6E3 + water system show that no adsorption occurs up to the critical micelle concentration, at which a sharp increase of adsorption is observed that is attributed to ad-micelle formation at the pore walls. Intriguingly, as the concentration is increased further, the surface excess of the amphiphile begins to decrease and eventually becomes negative, which corresponds to preferential adsorption of water rather than amphiphile at high amphiphile concentrations. The existence of such a surface-azeotropic point has not previously been reported in the surfactant adsorption field. Dissipative particle dynamics simulations were performed to reveal the structural origin of this transition from aggregative adsorption to surface depletion. The simulations indicate that this transition can be attributed to the repulsive interaction between head groups, causing depletion of the amphiphile in the region around the corona of the surface micelles.

KW - Adsorption

KW - mesoscale simulations

KW - nanopores

KW - surface azeotrope

KW - surfactant

U2 - 10.1080/00268976.2017.1299234

DO - 10.1080/00268976.2017.1299234

M3 - Journal article

AN - SCOPUS:85016093193

SN - 0026-8976

VL - 115

SP - 1408

EP - 1416

JO - Molecular Physics

JF - Molecular Physics

IS - 9-12

ER -