Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials

Poor crack resistance, high brittleness, and poor toughness are inherent limitations of traditional cement-based materials. Besides, cement-based materials have certain shortcomings in energy consumption and environmental protection. Therefore, improving the performance of cement-based materials bec...

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Autores principales: Liu Changjiang, Chen Fulian, Wu Yuyou, Zheng Zhoulian, Yang Jingwei, Yang Bo, Yang Jiangying, Hui David, Luo Yuanbing
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Publicado: De Gruyter 2021
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spelling oai:doaj.org-article:66de9e3a8a6e475cb100819d863828a72021-12-05T14:10:58ZResearch progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials2191-909710.1515/ntrev-2021-0080https://doaj.org/article/66de9e3a8a6e475cb100819d863828a72021-09-01T00:00:00Zhttps://doi.org/10.1515/ntrev-2021-0080https://doaj.org/toc/2191-9097Poor crack resistance, high brittleness, and poor toughness are inherent limitations of traditional cement-based materials. Besides, cement-based materials have certain shortcomings in energy consumption and environmental protection. Therefore, improving the performance of cement-based materials becomes a hot topic in related research. At the same time, the development of nanomaterials and technologies provides researchers with a new research idea: to enhance the performance of cement-based materials at the nanoscale level. Graphene oxide (GO) is one of the most representative nano-reinforcements. Due to its high surface area and excellent physical properties, GO has a surprising effect on improving the performance of cement-based materials. In addition, nanosilica (NS) and carbon nanotubes (CNTs) have excellent improvement on cement-based materials, and people also hope to further improve the performance of cement-based materials through the interaction of various nanomaterials. In this paper, the influence of GO on cement-based materials is reviewed by consulting a lot of correlative literature, mainly focusing on the following aspects: (i) The dispersion of GO in cement paste. (ii) The influence of GO on the properties of cement-based materials, including working performance, mechanical strength, microstructural characteristics, and durability. (iii) The effect of nanohybrid materials of GO, NS, and CNTs on cement-based materials, and the synergistic effects of various nanomaterials are reviewed for the first time. (iv) Evaluation of current progress. This paper aims to provide guidance for the study and application of GO-modified cement-based materials and nanohybrid materials.Liu ChangjiangChen FulianWu YuyouZheng ZhoulianYang JingweiYang BoYang JiangyingHui DavidLuo YuanbingDe Gruyterarticlegraphene oxidecement-based materialsnanohybrid materialssynergistic effectdevelopment and challengesnanomaterialsTechnologyTChemical technologyTP1-1185Physical and theoretical chemistryQD450-801ENNanotechnology Reviews, Vol 10, Iss 1, Pp 1208-1235 (2021)
institution DOAJ
collection DOAJ
language EN
topic graphene oxide
cement-based materials
nanohybrid materials
synergistic effect
development and challenges
nanomaterials
Technology
T
Chemical technology
TP1-1185
Physical and theoretical chemistry
QD450-801
spellingShingle graphene oxide
cement-based materials
nanohybrid materials
synergistic effect
development and challenges
nanomaterials
Technology
T
Chemical technology
TP1-1185
Physical and theoretical chemistry
QD450-801
Liu Changjiang
Chen Fulian
Wu Yuyou
Zheng Zhoulian
Yang Jingwei
Yang Bo
Yang Jiangying
Hui David
Luo Yuanbing
Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
description Poor crack resistance, high brittleness, and poor toughness are inherent limitations of traditional cement-based materials. Besides, cement-based materials have certain shortcomings in energy consumption and environmental protection. Therefore, improving the performance of cement-based materials becomes a hot topic in related research. At the same time, the development of nanomaterials and technologies provides researchers with a new research idea: to enhance the performance of cement-based materials at the nanoscale level. Graphene oxide (GO) is one of the most representative nano-reinforcements. Due to its high surface area and excellent physical properties, GO has a surprising effect on improving the performance of cement-based materials. In addition, nanosilica (NS) and carbon nanotubes (CNTs) have excellent improvement on cement-based materials, and people also hope to further improve the performance of cement-based materials through the interaction of various nanomaterials. In this paper, the influence of GO on cement-based materials is reviewed by consulting a lot of correlative literature, mainly focusing on the following aspects: (i) The dispersion of GO in cement paste. (ii) The influence of GO on the properties of cement-based materials, including working performance, mechanical strength, microstructural characteristics, and durability. (iii) The effect of nanohybrid materials of GO, NS, and CNTs on cement-based materials, and the synergistic effects of various nanomaterials are reviewed for the first time. (iv) Evaluation of current progress. This paper aims to provide guidance for the study and application of GO-modified cement-based materials and nanohybrid materials.
format article
author Liu Changjiang
Chen Fulian
Wu Yuyou
Zheng Zhoulian
Yang Jingwei
Yang Bo
Yang Jiangying
Hui David
Luo Yuanbing
author_facet Liu Changjiang
Chen Fulian
Wu Yuyou
Zheng Zhoulian
Yang Jingwei
Yang Bo
Yang Jiangying
Hui David
Luo Yuanbing
author_sort Liu Changjiang
title Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
title_short Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
title_full Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
title_fullStr Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
title_full_unstemmed Research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
title_sort research progress on individual effect of graphene oxide in cement-based materials and its synergistic effect with other nanomaterials
publisher De Gruyter
publishDate 2021
url https://doaj.org/article/66de9e3a8a6e475cb100819d863828a7
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