Tuesday, April 25, 2023

Enhanced performance of oxygen vacancies on CO2 adsorption and activation over different phases of ZrO2

Peer-Reviewed Publication

HIGHER EDUCATION PRESS

Enhanced performance of oxygen vacancies on CO2 adsorption and activation over different phases of ZrO2 

IMAGE: ACTIVATION PROCESS OF CO2 ON C-ZRO2, T-ZRO2, M-ZRO2 SURFACES WITH THE PRESENCE OF OXYGEN VACANCIES view more 

CREDIT: HIGHER EDUCATION PRESS LIMITED COMPANY

Excessive use of fossil energy causes global warming and other environmental problems. To reduce the greenhouse effect, two major greenhouse gases-CO2 and CH4 as the feedback are used to produce syngas (CO and H2) by CO2-CH4 reforming technique (DRM). The key to DRM is the choice of catalyst. The catalyst for DRM reaction mainly consists of two parts: the active metal and the support, in which a suitable support plays an important role in promoting the reaction activity and stability. Currently, ZrO2 is considered as a promising catalyst support due to the presence of oxygen vacancies. However, studies on the effect of oxygen vacancies on the ZrO2 surface for CO2 adsorption and activation processes are still lacking.

A research group of Juntian Niu from Taiyuan University of Technology investigated the effect of oxygen vacancies for the adsorption and activation of CO2 on the surface ZrO2 by density functional theory (DFT) calculations. They found that the oxygen vacancies contribute greatly to both the adsorption and activation of CO2, and the essence lies in oxygen vacancies greatly facilitate the charge transfer from the ZrO2 surface to the CO2 molecule. Additionally, it was found that t-ZrO2 with the presence of oxygen vacancies is most favorable to the adsorption and activation of CO2 by the comparison of different ZrO2 crystalline phases.

The new findings elucidated the role of oxygen vacancies in CO2 adsorption and activation for the preparation of high-performance DRM reaction catalysts using ZrO2. Meanwhile, it provided guidance for the design of CO2 high-efficient catalysts at an atomic level.

These findings were published in Frontiers in Energy on February 28.

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About Higher Education Press

Founded in May 1954, Higher Education Press Limited Company (HEP), affiliated with the Ministry of Education, is one of the earliest institutions committed to educational publishing after the establishment of P. R. China in 1949. After striving for six decades, HEP has developed into a major comprehensive publisher, with products in various forms and at different levels. Both for import and export, HEP has been striving to fill in the gap of domestic and foreign markets and meet the demand of global customers by collaborating with more than 200 partners throughout the world and selling products and services in 32 languages globally. Now, HEP ranks among China's top publishers in terms of copyright export volume and the world's top 50 largest publishing enterprises in terms of comprehensive strength.

The Frontiers Journals series published by HEP includes 28 English academic journals, covering the largest academic fields in China at present. Among the series, 12 have been indexed by SCI, 6 by EI, 2 by MEDLINE, 1 by A&HCI. HEP's academic monographs have won about 300 different kinds of publishing funds and awards both at home and abroad.

 

About Frontiers in Energy

Frontiers in Energy, a peer-reviewed international journal launched in January 2007, presents a unique platform for reporting the most advanced research and strategic thinking on energy technology. The Journal publishes review and mini-review articles, original research articles, perspective, news & highlights, viewpoints, comments, etc. by individual researchers and research groups. The journal is strictly peer-reviewed and accepts only original submissions in English. The scope of the Journal covers (but not limited to): energy conversion and utilization; renewable energy; energy storage; hydrogen and fuel cells; carbon capture, utilization and storage; advanced nuclear technology; smart grids and microgrids; power and energy systems; power cells and electric vehicles; building energy conservation, energy and environment; energy economy and policy, etc. Interdisciplinary papers are encouraged.

 

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