The Lewis acidic zeolite Sn-b is an important catalyst in the area of sustainable chemistry. Its ability to perform essential chemical transformations, such as isomerizations and oxidations, at high levels of activity and selectivity, whilst also possessing the favourable properties of a heterogeneous material, means that industrial interest is at an all time high. Nevertheless, some significant practical hurdles remain that currently curtail industrial implementation. Amongst these, the lengthy and complicated synthetic procedure, the low amount of active metal incorporated per kilogram of final catalyst, and the large crystallite sizes remain the most prohibitive. Recently, we reported a much more favourable route for the preparation o...
Zeolites modified by Lewis acidic metal centers such as Sn, Zr, and Hf are promising catalysts for n...
The concept of biorefinery, transforming biological feedstock into valuable chemicals, has gained in...
A highly active Sn site with Lewis acid properties is identified in post-synthetically synthesized S...
The Lewis acidic zeolite Sn-b is an important catalyst in the area of sustainable chemistry. Its abi...
Tin goes in: The solid Lewis acid Sn-zeolite β is obtained in a simple and scalable procedure (see s...
Sn-beta zeolite is a powerful Lewis acid catalyst. Recently it was shown that this material shows gr...
A two-step procedure for the post-synthetic preparation of Lewis acidic Sn-, Zr- and Ti-zeolite β is...
Sn-Beta has emerged as a state-of-the-art catalyst for a range of sustainable chemical transformatio...
© 2015 Elsevier Inc. All rights reserved. Snβ is probably one of the best water tolerating heterogen...
[EN] The former synthesis of TS-1 opened new catalytic opportunities for zeolites, especially for th...
Sn-Beta zeolite was prepared by acid dealumination of Beta zeolite, followed by dehydration and impr...
Lewis acidic zeolites are rapidly emerging liquid-phase Lewis acid catalysts. Nevertheless, their in...
Multifunctional catalysis is key to convert biomass mols. into useful chems. [1, 2]. A practical s...
Lewis acidic zeolites are rapidly emerging liquid-phase Lewis acid catalysts. Nevertheless, their in...
Zeolites modified by Lewis acidic metal centers such as Sn, Zr, and Hf are promising catalysts for n...
The concept of biorefinery, transforming biological feedstock into valuable chemicals, has gained in...
A highly active Sn site with Lewis acid properties is identified in post-synthetically synthesized S...
The Lewis acidic zeolite Sn-b is an important catalyst in the area of sustainable chemistry. Its abi...
Tin goes in: The solid Lewis acid Sn-zeolite β is obtained in a simple and scalable procedure (see s...
Sn-beta zeolite is a powerful Lewis acid catalyst. Recently it was shown that this material shows gr...
A two-step procedure for the post-synthetic preparation of Lewis acidic Sn-, Zr- and Ti-zeolite β is...
Sn-Beta has emerged as a state-of-the-art catalyst for a range of sustainable chemical transformatio...
© 2015 Elsevier Inc. All rights reserved. Snβ is probably one of the best water tolerating heterogen...
[EN] The former synthesis of TS-1 opened new catalytic opportunities for zeolites, especially for th...
Sn-Beta zeolite was prepared by acid dealumination of Beta zeolite, followed by dehydration and impr...
Lewis acidic zeolites are rapidly emerging liquid-phase Lewis acid catalysts. Nevertheless, their in...
Multifunctional catalysis is key to convert biomass mols. into useful chems. [1, 2]. A practical s...
Lewis acidic zeolites are rapidly emerging liquid-phase Lewis acid catalysts. Nevertheless, their in...
Zeolites modified by Lewis acidic metal centers such as Sn, Zr, and Hf are promising catalysts for n...
The concept of biorefinery, transforming biological feedstock into valuable chemicals, has gained in...
A highly active Sn site with Lewis acid properties is identified in post-synthetically synthesized S...