Monolithic aerogel photocatalysts: a review

Photocatalysis has been considered as one of the most promising technologies for solving environmental pollution and energy crisis. However, photocatalysts in the powder form usually suffer from the strong tendency to agglomerate and intricate operation for recycling, which significantly limit their...

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Published inJournal of materials chemistry. A, Materials for energy and sustainability Vol. 6; no. 3; pp. 754 - 775
Main Authors Wan, Wenchao, Zhang, Ruiyang, Ma, Minzhi, Zhou, Ying
Format Journal Article
LanguageEnglish
Published Cambridge Royal Society of Chemistry 2018
Subjects
adsorption
Aerogels
Clean energy
energy
Energy policy
Environmental cleanup
gases
Photocatalysis
Photocatalysts
Photochemical reactions
Photochemicals
Pollutants
pollution
Powder
Recoverability
remediation
surface area
Synthesis
Water pollution
Water splitting
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Abstract Photocatalysis has been considered as one of the most promising technologies for solving environmental pollution and energy crisis. However, photocatalysts in the powder form usually suffer from the strong tendency to agglomerate and intricate operation for recycling, which significantly limit their practical application. In comparison, monolithic aerogel photocatalysts with their highly macroscopic operability and recoverability as well as impressive specific surface area have attracted tremendous attention in recent years. With the development of synthesis technology, the types of aerogel photocatalysts have broadened from traditional oxide and chalcogenide aerogels to the current composite aerogels. Meanwhile, their application has also spread from primary physical adsorption to the present photochemical reactions including environmental remediation and clean energy production. In this review, the different synthesis strategies and photocatalytic applications of aerogel photocatalysts have been discussed. We summarize the currently available synthesis methods and widespread applications of aerogel photocatalysts. In particular, we highlight recent developments for the assembling of aerogel photocatalysts by direct synthesis and grafting photocatalysts to aerogel supports, as well as updated applications on the removal of aqueous pollutants, water splitting and gas phase photocatalysis. Finally, we outline the challenges and potential advances associated with the aerogel photocatalysts for future scientific research and commercial applications. This review has summarized the recent developments of aerogel photocatalysts along with their fabrication strategies and photocatalytic applications.
AbstractList Photocatalysis has been considered as one of the most promising technologies for solving environmental pollution and energy crisis. However, photocatalysts in the powder form usually suffer from the strong tendency to agglomerate and intricate operation for recycling, which significantly limit their practical application. In comparison, monolithic aerogel photocatalysts with their highly macroscopic operability and recoverability as well as impressive specific surface area have attracted tremendous attention in recent years. With the development of synthesis technology, the types of aerogel photocatalysts have broadened from traditional oxide and chalcogenide aerogels to the current composite aerogels. Meanwhile, their application has also spread from primary physical adsorption to the present photochemical reactions including environmental remediation and clean energy production. In this review, the different synthesis strategies and photocatalytic applications of aerogel photocatalysts have been discussed. We summarize the currently available synthesis methods and widespread applications of aerogel photocatalysts. In particular, we highlight recent developments for the assembling of aerogel photocatalysts by direct synthesis and grafting photocatalysts to aerogel supports, as well as updated applications on the removal of aqueous pollutants, water splitting and gas phase photocatalysis. Finally, we outline the challenges and potential advances associated with the aerogel photocatalysts for future scientific research and commercial applications. This review has summarized the recent developments of aerogel photocatalysts along with their fabrication strategies and photocatalytic applications.
Photocatalysis has been considered as one of the most promising technologies for solving environmental pollution and energy crisis. However, photocatalysts in the powder form usually suffer from the strong tendency to agglomerate and intricate operation for recycling, which significantly limit their practical application. In comparison, monolithic aerogel photocatalysts with their highly macroscopic operability and recoverability as well as impressive specific surface area have attracted tremendous attention in recent years. With the development of synthesis technology, the types of aerogel photocatalysts have broadened from traditional oxide and chalcogenide aerogels to the current composite aerogels. Meanwhile, their application has also spread from primary physical adsorption to the present photochemical reactions including environmental remediation and clean energy production. In this review, the different synthesis strategies and photocatalytic applications of aerogel photocatalysts have been discussed. We summarize the currently available synthesis methods and widespread applications of aerogel photocatalysts. In particular, we highlight recent developments for the assembling of aerogel photocatalysts by direct synthesis and grafting photocatalysts to aerogel supports, as well as updated applications on the removal of aqueous pollutants, water splitting and gas phase photocatalysis. Finally, we outline the challenges and potential advances associated with the aerogel photocatalysts for future scientific research and commercial applications.
Author Ma, Minzhi
Wan, Wenchao
Zhang, Ruiyang
Zhou, Ying
AuthorAffiliation The Center of New Energy Materials and Technology
Southwest Petroleum University
School of Materials Science and Engineering
State Key Laboratory of Oil and Gas Reservoir Geology and Exploitation
AuthorAffiliation_xml – sequence: 0
  name: Southwest Petroleum University
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  name: School of Materials Science and Engineering
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Author_xml – sequence: 1
  givenname: Wenchao
  surname: Wan
  fullname: Wan, Wenchao
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  givenname: Ruiyang
  surname: Zhang
  fullname: Zhang, Ruiyang
– sequence: 3
  givenname: Minzhi
  surname: Ma
  fullname: Ma, Minzhi
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  givenname: Ying
  surname: Zhou
  fullname: Zhou, Ying
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ISSN 2050-7488
2050-7496
IngestDate Fri Jul 11 13:36:01 EDT 2025
Mon Jun 30 12:02:38 EDT 2025
Thu Apr 24 23:03:35 EDT 2025
Tue Jul 01 03:13:46 EDT 2025
Tue Dec 17 20:59:16 EST 2024
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Notes Wenchao Wan received his BSc from the Shengli College China University of Petroleum. In 2016, he received his MSc from Southwest Petroleum University (SWPU) under the supervision of Prof. Ying Zhou. He is currently a PhD candidate. His research interest is focusing on the design and synthesis of three-dimensional aerogel materials for energy and environmental applications.
2
reforming of methane under the supervision of Prof. Ying Zhou.
characterization techniques.
Ying Zhou received his BSc and MSc from Central South University and Chinese Academy of Sciences, respectively. In 2010, he received his PhD at the University of Zurich (UZH) under the supervision of Prof. Greta R. Patzke. He then continued his work with a postdoctoral Forschungskredit grant from UZH. He was also awarded a fellowship by the Alexander von Humboldt Foundation at Karlsruhe Institute of Technology with Prof. Jan-Dierk Grunwaldt and was a visiting professor at Kyoto University. He currently holds a professorship at Southwest Petroleum University. His research interest is in the clean utilization of oil and gas and environmental remediation materials as well as the related
Minzhi Ma received his BSc from Xuchang University, Xuchang in 2016. He is presently pursuing his MSc degree in materials science and engineering at Southwest Petroleum University and working on the catalyst design for dry (CO
Ruiyang Zhang received his BSc degree from Henan Polytechnic University in 2012 and MSc degree from Southwest Petroleum University in 2017. Currently he is a PhD candidate at Southwest Petroleum University with Prof. Ying Zhou. His main research interest is in the preparation of two-dimensional aerogel materials for environmental remediation and photocatalytic clean energy production.
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PublicationTitle Journal of materials chemistry. A, Materials for energy and sustainability
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Publisher Royal Society of Chemistry
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Snippet Photocatalysis has been considered as one of the most promising technologies for solving environmental pollution and energy crisis. However, photocatalysts in...
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SubjectTerms adsorption
Aerogels
Clean energy
energy
Energy policy
Environmental cleanup
gases
Photocatalysis
Photocatalysts
Photochemical reactions
Photochemicals
Pollutants
pollution
Powder
Recoverability
remediation
surface area
Synthesis
Water pollution
Water splitting
Title Monolithic aerogel photocatalysts: a review
URI https://www.proquest.com/docview/2010896199
https://www.proquest.com/docview/2237517493
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