Your search keyword '"Tom Hauffman"' showing total 3 results

1. Molecular Characterization of Multiple Bonding Interactions at the Steel Oxide–Aminopropyl triethoxysilane Interface by ToF-SIMS

Author

Kristof Marcoen, Mélanie Gauvin, Joost De Strycker, Herman Terryn, and Tom Hauffman

Subjects

Chemistry, QD1-999

Published

2020

2. Amino-Alkylphosphonate-Grafted TiO2: How the Alkyl Chain Length Impacts the Surface Properties and the Adsorption Efficiency for Pd

Author

Nick Gys, Rui An, Bram Pawlak, David Vogelsang, Kenny Wyns, Kitty Baert, Alexander Vansant, Frank Blockhuys, Peter Adriaensens, Tom Hauffman, Bart Michielsen, Steven Mullens, and Vera Meynen

Subjects

PLATINUM, Science & Technology, STABILITY, PALLADIUM, Chemistry, Multidisciplinary, General Chemical Engineering, OXIDE, General Chemistry, ACIDS, PHOSPHONATE MONOLAYERS, Chemistry, SELF-ASSEMBLED MONOLAYERS, AMINOPROPYL GROUPS, Physical Sciences, NANOPARTICLES, FUNCTIONALIZATION

Abstract

Amino-alkylphosphonic acid-grafted TiO2 materials are of increasing interest in a variety of applications such as metal sorption, heterogeneous catalysis, CO2 capture, and enzyme immobilization. To date, systematic insights into the synthesis-properties-performance correlation are missing for such materials, albeit giving important know-how towards their applicability and limitations. In this work, the impact of the chain length and modification conditions (concentration and temperature) of amino-alkylphosphonic acid-grafted TiO2 on the surface properties and adsorption performance of palladium is studied. Via grafting with aminomethyl-, 3-aminopropyl-, and 6-aminohexylphosphonic acid, combined with the spectroscopic techniques (DRIFT, 31P NMR, XPS) and zeta potential measurements, differences in surface properties between the C1, C3, and C6 chains are revealed. The modification degree decreases with increasing chain length under the same synthesis conditions, indicative of folded grafted groups that sterically shield an increasing area of binding sites with increasing chain length. Next, all techniques confirm the different surface interactions of a C1 chain compared to a C3 or C6 chain. This is in line with palladium adsorption experiments, where only for a C1 chain, the adsorption efficiency is affected by the precursor concentration used for modification. The absence of a straightforward correlation between the number of free NH2 groups and the adsorption capacity for the different chain lengths indicates that other chain-length-specific surface interactions are controlling the adsorption performance. The increasing pH stability in the order of C1 < C3 < C6 can possibly be associated to a higher fraction of inaccessible hydrophilic sites due to the presence of folded structures. Lastly, the comparison of adsorption performance and pH stability with 3-aminopropyl(triethoxysilane)-grafted TiO2 reveals the applicability of both grafting methods depending on the envisaged pH during sorption. ispartof: ACS OMEGA vol:7 issue:49 pages:45409-45421 ispartof: location:United States status: published

Published

2022

3. Molecular Characterization of Multiple Bonding Interactions at the Steel Oxide–Aminopropyl triethoxysilane Interface by ToF-SIMS

Author

Herman Terryn, Tom Hauffman, Mélanie Gauvin, Joost De Strycker, Kristof Marcoen, Faculty of Engineering, Materials and Chemistry, Materials and Surface Science & Engineering, and Electrochemical and Surface Engineering

Subjects

Materials science, Silanes, Carbon steel, General Chemical Engineering, fungi, technology, industry, and agriculture, Oxide, General Chemistry, engineering.material, Multiple bonds, Article, Metal, chemistry.chemical_compound, Chemistry, chemistry, Chemical engineering, visual_art, Triethoxysilane, visual_art.visual_art_medium, engineering, QD1-999

Abstract

Organofunctional silanes are applied as coupling agents between organic coatings and low carbon steel substrates to promote adhesion. Although the metal oxide-silane interface plays an important role in the performance of the entire overlying coating system, it remains challenging to obtain a clear understanding of the interfacial molecular bonding mechanism and its influence on adhesion. In this work, time-of-flight secondary ion mass spectrometry is used to study interfacial interactions between aminopropyl triethoxysilane (APS) and low carbon steel. APS is shown to bond to the steel substrate through silanol steel and amine-steel interactions, and coatings are cured at varying temperatures to evaluate the influence of curing on these different types of bonding interactions. Unambiguous evidence for hydrogen bond interactions between APS silanol groups and steel surface hydroxyl groups is provided for the first time in this work through deuteration of the steel substrate and allows to tackle long-lasting doubts about the most wide-spread bonding theory that has been postulated for silane adsorption on metals.

Published

2020