H.L. Castricum scite author profile

Hybrid organically linked silica is a highly promising class of materials for the application in energy‐efficient molecular separation membranes. Its high stability allows operation under aggressive working conditions. Herein is reported the tailoring of the separation performance of these hybrid silica membranes by adjusting the size, flexibility, shape, and electronic structure of the organic bridging group. A single generic procedure is applied to synthesize nanoporous membranes from bridged silsesquioxane precursors with different reactivities. Membranes with short alkylene (CH2 and C2H4) bridging groups show high H2/N2 permeance ratios, related to differences in molecular size. The highest CO2/H2 permeance ratios, related to the affinity of adsorption in the material, are obtained for longer (C8H16) alkylene and aryl bridges. Materials with long flexible alkylene bridges have a hydrophobic surface and show strongly temperature‐dependent molecular transport as well as a high n‐butanol flux in a pervaporation process, which is indicative of organic polymerlike properties. The versatility of the bridging group offers an extensive toolbox to tune the nanostructure and the affinity of hybrid silica membranes and by doing so to optimize the performance towards specific separation challenges. This provides excellent prospects for industrial applications such as carbon capture and biofuel production.

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Hybrid ceramic nanosieves: stabilizing nanopores with organic links

Castricum

et al. 2008

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High-performance hybrid pervaporation membranes with superior hydrothermal and acid stability

Castricum

Kreiter

Veen

et al. 2008

Journal of Membrane Science

117

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Studies of water and ice in hydrophilic and hydrophobic mesoporous silicas: pore characterisation and phase transformations

Jelassi

Castricum

Bellissent-Funel

et al. 2010

Phys. Chem. Chem. Phys.

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A study has been made as a function of temperature of the phase transformation of water and ice in two samples of mesoporous silica gel with pore diameters of ∼50Å. One sample was modified by coating with a layer of trimethylchlorosilane, giving a predominantly hydrophobic internal surface, whereas the unmodified sample has a hydrophilic interface. The pore structure was characterised by nitrogen gas adsorption and NMR cryoporometry and the melting/freezing behaviour of water and ice in the pores was studied by DSC and neutron diffraction for cooling and heating cycles, covering a range of 200 to 300K. Measurements were made for several filling-factors in the range 0.2 to 0.9. The results show a systematic difference in the form of ice created in each of the samples. The non-modified sample gives similar results to previous studies with hydrophilic silicas, exhibiting a defective form of cubic ice superimposed on a more disordered pattern that changes with temperature and has been characterised as 'plastic' ice [Liu et al, 2006, Webber et al, 2007. The modified sample has similar general features but displays important variability in the ice transformation features, particularly for the case of the low filling-factor (f=0.2). The results exhibit a complex temperaturedependent variation of the crystalline and disordered components that are substantially altered for the different filling-factors. *

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Pushing membrane stability boundaries with HybSi® pervaporation membranes

Veen

Rietkerk

Shanahan

et al. 2011

Journal of Membrane Science

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Stable Hybrid Silica Nanosieve Membranes for the Dehydration of Lower Alcohols

et al. 2009

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Hydrophobic modification of γ-alumina membranes with organochlorosilanes

Sah¹,

Castricum

Bliek

et al. 2004

Journal of Membrane Science

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H.L. Castricum

Hydrothermally stable molecular separation membranes from organically linked silica

Tailoring the Separation Behavior of Hybrid Organosilica Membranes by Adjusting the Structure of the Organic Bridging Group

Hybrid ceramic nanosieves: stabilizing nanopores with organic links

High-performance hybrid pervaporation membranes with superior hydrothermal and acid stability

Studies of water and ice in hydrophilic and hydrophobic mesoporous silicas: pore characterisation and phase transformations

Pushing membrane stability boundaries with HybSi® pervaporation membranes

Stable Hybrid Silica Nanosieve Membranes for the Dehydration of Lower Alcohols

Hydrophobic modification of γ-alumina membranes with organochlorosilanes

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