Early-strength mechanisms, carbon sequestration, and phytocompatibility of ecological porous concrete synergistically modified with triethanolamine and nano-silica: Hydration kinetics and microstructural mechanisms

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成果类型：

期刊论文

作者：

Zhu, Yangyi;Yin, Jian*;Li, Sijiao;Liu, Sizhe;He, Shuai;...

通讯作者：

Yin, Jian;Li, SJ

作者机构：

[Yin, Jian; Li, Sijiao; Yin, J; He, Shuai; Chen, Yihao; Zhu, Yangyi; Li, SJ; Liu, Sizhe] Cent South Univ Forestry & Technol, Sch Civil Engn, Changsha 410004, Peoples R China.

通讯机构：

[Yin, J; Li, SJ ] C

Cent South Univ Forestry & Technol, Sch Civil Engn, Changsha 410004, Peoples R China.

语种：

英文

关键词：

Ecological porous concrete;Triethanolamine;Nano-silica;Hydration kinetics;Micromechanism;Carbon sequestration

期刊：

Journal of Building Engineering

ISSN：

2352-7102

年：

2025

卷：

107

页码：

112669

DOI：

10.1016/j.jobe.2025.112669

基金类别：

CRediT authorship contribution statement Yangyi Zhu: Writing – original draft, Methodology, Data curation, Conceptualization. Jian Yin: Writing – review & editing, Supervision, acquisition. Sijiao Li: Writing – review & editing, Validation, Resources. Sizhe Liu: Validation, Investigation. Shuai He: Visualization, Investigation. Yihao Chen: Writing – review & editing, Investigation.

机构署名：

本校为第一且通讯机构

院系归属：

土木工程学院

摘要：

To address the specific demands for early-strength materials in ecological slope emergency restoration projects and ecological slope construction in cold regions, this study has developed Ecological Porous Concrete (EPC) with low-alkali characteristics and enhanced early-strength advantages through a synergistic mechanism of alkalinity regulation and strength enhancement. This provides new material support for advancing the ecological restoration technology system within the context of carbon neutrality . In this study, we systematically investigated the influences of triethanolamine (TEA) and...

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Early-strength mechanisms, carbon sequestration, and phytocompatibility of ecological porous concrete synergistically modified with triethanolamine and nano-silica: Hydration kinetics and microstructural mechanisms

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