Surface Modification of Porous Carbon Nanomaterials for Water Vapor Adsorption

Sun, Shengnan; Yu, Qiongfen; Li, Ming; Zhao, Hong; Wang, Yunfeng; Zhang, Ying

doi:10.1021/acsanm.2c05205

Cited by 13 publications

(5 citation statements)

References 54 publications

(81 reference statements)

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“…In recent years, it has been a preferred strategy for the assembly of mineral nanostructures on membranes by spontaneous mineralization that achieved through modifying the polymer membranes and then adding mineralized raw materials. [68][69][70] This type of study focuses on constructing groups with strong electrical, polar, physical, and chemical interactions with mineral ions on the membrane surface. By doing so, it creates crystal growth sites on the membrane surface, leading to thermodynamically spontaneous and orderly nucleation and crystal growth in the pre-mineralized body fluids.…”

Section: Interfacial Compatilization Inducing Mineralizationmentioning

confidence: 99%

Construction of Mineralization Nanostructures in Polymers for Mechanical Enhancement and Functionalization

Lv,

Wang,

Zhang

2024

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Mineralization capable of growing inorganic nanostructures efficiently, orderly, and spontaneously shows great potential for application in the construction of high‐performance organic–inorganic composites. As a thermodynamically spontaneous solid‐phase crystallization reaction involving dual organic and inorganic components, mineralization allows for the self‐assembly of sophisticated and exclusive nanostructures within a polymer matrix. It results in a diversity of functions such as enhanced strength, toughness, electrical conductivity, selective permeability, and biocompatibility. While there are previous reviews discussing the progress of mineralization reactions, many of them overlook the significant benefits of interfacial regulation and functionalization that come from the incorporation of mineralized structures into polymers. Focusing on different means of assembly of mineralized nanostructures in polymer, the work analyzes their design principles and implementation strategies. Then, their different advantages and disadvantages are analyzed by combining nanostructures with organic substrates as well as involving the basis of different functionalizations. It is anticipated to provide insights and guidance for the future development of mineralized polymer composites and their application designs.

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Section: Interfacial Compatilization Inducing Mineralizationmentioning

confidence: 99%

Construction of Mineralization Nanostructures in Polymers for Mechanical Enhancement and Functionalization

Lv,

Wang,

Zhang

2024

Small

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“…Other materials, including graphene and MXene, also possess architectures lending to dispersibility in the fabrication of energy device such as solar cells. [44,45] Consideration will be given at the end of this section to some alternative materials as a basis for comparing the dispersibility of CNTs.…”

Section: Cnt Architecture and Architectures Of Alternative Materialsmentioning

confidence: 99%

Recent Advances in Dispersant Technology for Carbon Nanotubes toward Energy Device Applications

Choi,

Nacpil,

Han

et al. 2024

Adv Energy and Sustain Res

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Carbon nanotubes (CNTs) are of interest in various industries owing to their high aspect ratio, electrical conductivity, and other properties. By maximizing the number of CNTs in their solvents or matrices, the electrical and mechanical performance in applications such as batteries, sensors, and transistors can be enhanced. However, the hydrophobicity of CNTs’ surface induces aggregation that adversely impacts their performance. To overcome this obstacle, many researchers have been designing novel dispersants with performances exceeding that of existing commercial dispersants. This article reviews contemporary studies on CNT dispersants from 2015 to 2022, along with the comprehensive features of CNTs depending on their chirality, number of walls, synthesis methods, and functionalization. Studies of CNT dispersants are primarily organized according to whether aqueous or organic solvents are used. This review article provides a clear perspective of CNT dispersants development today and how to design new CNT dispersants depending on the solvents. A conclusion is given to identify major challenges to the implementation of CNT dispersion and an outlook on future avenues of research.

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“…37 MoO 3 with oxygen vacancies exhibited localized surface plasmon resonance (LSPR) effects, and the LSPR effect can broaden the light absorption range of semiconductors, thus improving the light absorption capacity. [38][39][40][41] In addition, oxygen vacancies can act as an electron trap to impede the recombination of photogenerated carriers. 42 Therefore, MoO 3−x also has a lower band gap and higher photogenerated charge separation efficiency.…”

Section: Introductionmentioning

confidence: 99%

An investigation on a WO₃/MoO_3−x heterojunction photocatalyst for excellent photocatalytic performance and enhanced molecular oxygen activation ability

Shao,

You,

Wan

et al. 2024

React. Chem. Eng.

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Surface Modification of Porous Carbon Nanomaterials for Water Vapor Adsorption

Cited by 13 publications

References 54 publications

Construction of Mineralization Nanostructures in Polymers for Mechanical Enhancement and Functionalization

Construction of Mineralization Nanostructures in Polymers for Mechanical Enhancement and Functionalization

Recent Advances in Dispersant Technology for Carbon Nanotubes toward Energy Device Applications

An investigation on a WO₃/MoO_3−x heterojunction photocatalyst for excellent photocatalytic performance and enhanced molecular oxygen activation ability

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Surface Modification of Porous Carbon Nanomaterials for Water Vapor Adsorption

Cited by 13 publications

References 54 publications

Construction of Mineralization Nanostructures in Polymers for Mechanical Enhancement and Functionalization

Construction of Mineralization Nanostructures in Polymers for Mechanical Enhancement and Functionalization

Recent Advances in Dispersant Technology for Carbon Nanotubes toward Energy Device Applications

An investigation on a WO3/MoO3−x heterojunction photocatalyst for excellent photocatalytic performance and enhanced molecular oxygen activation ability

Contact Info

Product

Resources

About

An investigation on a WO₃/MoO_3−x heterojunction photocatalyst for excellent photocatalytic performance and enhanced molecular oxygen activation ability