Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity

Research output: Contribution to journalJournal articleResearchpeer-review

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Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity. / Juhl, Klaus; Bovet, Nicolas Emile; Hassenkam, Tue; Dideriksen, Knud; Pedersen, Christian Schack; Jensen, Christina Mernøe; Okhrimenko, Denis; Stipp, Susan Louise Svane.

In: Langmuir, Vol. 30, No. 29, 2014, p. 8741-8750.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Juhl, K, Bovet, NE, Hassenkam, T, Dideriksen, K, Pedersen, CS, Jensen, CM, Okhrimenko, D & Stipp, SLS 2014, 'Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity', Langmuir, vol. 30, no. 29, pp. 8741-8750. https://doi.org/10.1021/la500791m

APA

Juhl, K., Bovet, N. E., Hassenkam, T., Dideriksen, K., Pedersen, C. S., Jensen, C. M., Okhrimenko, D., & Stipp, S. L. S. (2014). Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity. Langmuir, 30(29), 8741-8750. https://doi.org/10.1021/la500791m

Vancouver

Juhl K, Bovet NE, Hassenkam T, Dideriksen K, Pedersen CS, Jensen CM et al. Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity. Langmuir. 2014;30(29):8741-8750. https://doi.org/10.1021/la500791m

Author

Juhl, Klaus ; Bovet, Nicolas Emile ; Hassenkam, Tue ; Dideriksen, Knud ; Pedersen, Christian Schack ; Jensen, Christina Mernøe ; Okhrimenko, Denis ; Stipp, Susan Louise Svane. / Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity. In: Langmuir. 2014 ; Vol. 30, No. 29. pp. 8741-8750.

Bibtex

@article{8a5a199783bc444d9c844652aa4a7144,
title = "Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity",
abstract = "We investigated the adhesion of two functional groups to α-alumina as a model for the adsorption of organic molecules on clay minerals. Interactions between organic compounds and clay minerals play an important role in processes such as drinking water treatment, remediation of contaminated soil, oil recovery, and fabricating complicated nanomaterials, and there have been claims that organic compound-clay mineral interaction created the ordering that is necessary for the genesis of life. In many organisms, interaction between organic molecules and biominerals makes it possible to control the growth of bones, teeth, and shells. Adhesion of carboxylic acid, -COO(H), and pyridine, -C5H5N(H+), on the {0001} plane of α-alumina wafers has been investigated with atomic force microscopy (AFM) in chemical force mapping (CFM) mode. Both functional groups adhered to α-alumina in deionized water at pH < 5, and adhesion decreased as NaCl or CaCl2 concentration increased. X-ray photoelectron spectroscopy (XPS) showed that Na+ and Ca2+ adsorbed to the α-alumina surface at pH < 5, decreasing surface interaction with the carboxylic acid and pyridine groups. We interpret the results as evidence that the tips adhere to alumina through hydrogen bonding when only water is present. In solutions containing NaCl and CaCl2, cations are adsorbed but Cl- is not. When NaCl solutions are replaced by CaCl2, Ca2+ replaces Na+, but rinsing with ultrapure deionized water (pH 5.6) could not restore the original protonated surface. The results demonstrate that the alumina surface at pH 3 has a higher affinity for inorganic cations than for -COO(H) or -C5H5N(H+), in spite of the known positive surface charge of α-alumina {0001} wafers. These results demonstrate that solution salinity plays an important role in surface properties, controlling surface tension (i.e., contact angle) and adsorption affinity on α-alumina and, by analogy, on clay minerals.",
author = "Klaus Juhl and Bovet, {Nicolas Emile} and Tue Hassenkam and Knud Dideriksen and Pedersen, {Christian Schack} and Jensen, {Christina Mern{\o}e} and Denis Okhrimenko and Stipp, {Susan Louise Svane}",
year = "2014",
doi = "10.1021/la500791m",
language = "English",
volume = "30",
pages = "8741--8750",
journal = "Langmuir",
issn = "0743-7463",
publisher = "American Chemical Society",
number = "29",

}

RIS

TY - JOUR

T1 - Change in organic molecule adhesion on α-alumina (Sapphire) with change in NaCl and CaCl2 solution salinity

AU - Juhl, Klaus

AU - Bovet, Nicolas Emile

AU - Hassenkam, Tue

AU - Dideriksen, Knud

AU - Pedersen, Christian Schack

AU - Jensen, Christina Mernøe

AU - Okhrimenko, Denis

AU - Stipp, Susan Louise Svane

PY - 2014

Y1 - 2014

N2 - We investigated the adhesion of two functional groups to α-alumina as a model for the adsorption of organic molecules on clay minerals. Interactions between organic compounds and clay minerals play an important role in processes such as drinking water treatment, remediation of contaminated soil, oil recovery, and fabricating complicated nanomaterials, and there have been claims that organic compound-clay mineral interaction created the ordering that is necessary for the genesis of life. In many organisms, interaction between organic molecules and biominerals makes it possible to control the growth of bones, teeth, and shells. Adhesion of carboxylic acid, -COO(H), and pyridine, -C5H5N(H+), on the {0001} plane of α-alumina wafers has been investigated with atomic force microscopy (AFM) in chemical force mapping (CFM) mode. Both functional groups adhered to α-alumina in deionized water at pH < 5, and adhesion decreased as NaCl or CaCl2 concentration increased. X-ray photoelectron spectroscopy (XPS) showed that Na+ and Ca2+ adsorbed to the α-alumina surface at pH < 5, decreasing surface interaction with the carboxylic acid and pyridine groups. We interpret the results as evidence that the tips adhere to alumina through hydrogen bonding when only water is present. In solutions containing NaCl and CaCl2, cations are adsorbed but Cl- is not. When NaCl solutions are replaced by CaCl2, Ca2+ replaces Na+, but rinsing with ultrapure deionized water (pH 5.6) could not restore the original protonated surface. The results demonstrate that the alumina surface at pH 3 has a higher affinity for inorganic cations than for -COO(H) or -C5H5N(H+), in spite of the known positive surface charge of α-alumina {0001} wafers. These results demonstrate that solution salinity plays an important role in surface properties, controlling surface tension (i.e., contact angle) and adsorption affinity on α-alumina and, by analogy, on clay minerals.

AB - We investigated the adhesion of two functional groups to α-alumina as a model for the adsorption of organic molecules on clay minerals. Interactions between organic compounds and clay minerals play an important role in processes such as drinking water treatment, remediation of contaminated soil, oil recovery, and fabricating complicated nanomaterials, and there have been claims that organic compound-clay mineral interaction created the ordering that is necessary for the genesis of life. In many organisms, interaction between organic molecules and biominerals makes it possible to control the growth of bones, teeth, and shells. Adhesion of carboxylic acid, -COO(H), and pyridine, -C5H5N(H+), on the {0001} plane of α-alumina wafers has been investigated with atomic force microscopy (AFM) in chemical force mapping (CFM) mode. Both functional groups adhered to α-alumina in deionized water at pH < 5, and adhesion decreased as NaCl or CaCl2 concentration increased. X-ray photoelectron spectroscopy (XPS) showed that Na+ and Ca2+ adsorbed to the α-alumina surface at pH < 5, decreasing surface interaction with the carboxylic acid and pyridine groups. We interpret the results as evidence that the tips adhere to alumina through hydrogen bonding when only water is present. In solutions containing NaCl and CaCl2, cations are adsorbed but Cl- is not. When NaCl solutions are replaced by CaCl2, Ca2+ replaces Na+, but rinsing with ultrapure deionized water (pH 5.6) could not restore the original protonated surface. The results demonstrate that the alumina surface at pH 3 has a higher affinity for inorganic cations than for -COO(H) or -C5H5N(H+), in spite of the known positive surface charge of α-alumina {0001} wafers. These results demonstrate that solution salinity plays an important role in surface properties, controlling surface tension (i.e., contact angle) and adsorption affinity on α-alumina and, by analogy, on clay minerals.

U2 - 10.1021/la500791m

DO - 10.1021/la500791m

M3 - Journal article

C2 - 24988276

AN - SCOPUS:84904962608

VL - 30

SP - 8741

EP - 8750

JO - Langmuir

JF - Langmuir

SN - 0743-7463

IS - 29

ER -

ID: 130941486