Defect-rich TiO2 in situ evolved from MXene for efficiently oxidative dehydrogenation of ethane

Zhou, Yanliang; Li, Xiaoyu; Chai, Yicong; Wu, Zihao; Lin, Jian; Pan, Xiaoli; Han, Yujia; Li, Lin; Qi, Haifeng; Su, Yang; Kang, Leilei; Wang, Xiaodong

doi:10.21203/rs.3.rs-85939/v1

Cited by 1 publication

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“…Zhou et al used Ti 3 C 2 T x as a precursor to produce a defect-rich TiO 2 catalyst under ethane oxidative dehydrogenation conditions . The Ti and oxygen vacancies in the MXene derived oxide are believed to decrease the activation energy barrier of ethane and increase the rate of reoxidation of the catalyst . It is important to note that oxidation of MXenes allows synthesis of oxides with unusual 2D morphology that may not be achieved by other methods. , These studies indicate the potential for the use of MXenes as heterogeneous catalysts and as precursors to produce metal oxide catalysts with unique morphology and properties.…”

Section: Introductionmentioning

confidence: 99%

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MXene Aerogel Derived Ultra-Active Vanadia Catalyst for Selective Conversion of Sustainable Alcohols to Base Chemicals

Oefner

Shuck

Schumacher

et al. 2023

ACS Appl. Mater. Interfaces

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Selective oxidation reactions are an important class of the current chemical industry and will be highly important for future sustainable chemical production. Especially, the selective oxidation of primary alcohols is expected to be of high future interest, as alcohols can be obtained on technical scales from biomass fermentation. The oxidation of primary alcohols produces aldehydes, which are important intermediates. While selective methanol oxidation is industrially established, the commercial catalyst suffers from deactivation. Ethanol selective oxidation is not commercialized but would give access to sustainable acetaldehyde production when using renewable ethanol. In this work, it is shown that employing 2D MXenes as building blocks allows one to design a nanostructured oxide catalyst composed of mixed valence vanadium oxides, which outperforms on both reactions known materials by nearly an order of magnitude in activity, while showing high selectivity and stability. The study shows that the synthesis route employing 2D materials is key to obtain these attractive catalysts. V 4 C 3 T x MXene structured as an aerogel precursor needs to be employed and mildly oxidized in an alcohol and oxygen atmosphere to result in the aspired nanostructured catalyst composed of mixed valence VO 2 , V 6 O 13 , and V 3 O 7 . Very likely, the bulk stable reduced valence state of the material together coupled with the nanorod arrangement allows for unprecedented oxygen mobility as well as active sites and results in an ultra-active catalyst.

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