Developing green and economical low-alkalinity seawater sea sand concrete via innovative processing underground sediment
Developing green and economical low-alkalinity seawater sea sand concrete via innovative processing underground sediment
Large-scale expansion of urban underground space has led to the accumulation of substantial sediment. Now the primary disposal approach involves long-distance transport followed by dumping in open areas or landfills, incurring excessive deposition and causing landslides. To tackle this concern, a novel processing scheme that transforms sediment into supplementary cementitious material is proposed for preparing sustainable seawater sea sand concrete (SWSSC). Notably, it is determined that this transformed sediment improves cement hydration and reduces cement dosage, achieving a 35% reduction in CO2 emissions compared to traditional SWSSC with identical strength according to life cycle assessment. Furthermore, it offers the additional benefit of cost-effective. Microanalysis has demonstrated that the recycled sediment reacts with calcium hydroxide and produces secondary calcium-silicate-hydrate gel, contributing to the mechanical properties and decrease in alkalinity of SWSSC. A design model for SWSSC is proposed, focusing on alkalinity, mechanical strength, and environmental benefits. This proposed model enhances application of SWSSC in construction, catering to specialized marine engineering structures, like artificial islands, harbors and offshore structures. This study contributes to a large-scale processing strategy of sediment and provides an economical and green alternative construction material for sustainable infrastructures.
Zhou, Ao
5b42c2a4-26b2-416e-ab3c-446f1ece7a20
Chen, Jialiang
3e517aa7-6579-4458-b4a3-e8d1c99910dd
Li, Kexuan
d9a41130-8fca-4da4-adc0-01acbdd3f5d7
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Lu, Jian-Xin
8afbe07c-9a32-406a-bd41-7c86794a373a
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
13 February 2024
Zhou, Ao
5b42c2a4-26b2-416e-ab3c-446f1ece7a20
Chen, Jialiang
3e517aa7-6579-4458-b4a3-e8d1c99910dd
Li, Kexuan
d9a41130-8fca-4da4-adc0-01acbdd3f5d7
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Lu, Jian-Xin
8afbe07c-9a32-406a-bd41-7c86794a373a
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
Zhou, Ao, Chen, Jialiang, Li, Kexuan, Liu, Tiejun, Lu, Jian-Xin, Zou, Dujian and Li, Ye
(2024)
Developing green and economical low-alkalinity seawater sea sand concrete via innovative processing underground sediment.
Journal of Cleaner Production, 443, [140927].
(doi:10.1016/j.jclepro.2024.140927).
Abstract
Large-scale expansion of urban underground space has led to the accumulation of substantial sediment. Now the primary disposal approach involves long-distance transport followed by dumping in open areas or landfills, incurring excessive deposition and causing landslides. To tackle this concern, a novel processing scheme that transforms sediment into supplementary cementitious material is proposed for preparing sustainable seawater sea sand concrete (SWSSC). Notably, it is determined that this transformed sediment improves cement hydration and reduces cement dosage, achieving a 35% reduction in CO2 emissions compared to traditional SWSSC with identical strength according to life cycle assessment. Furthermore, it offers the additional benefit of cost-effective. Microanalysis has demonstrated that the recycled sediment reacts with calcium hydroxide and produces secondary calcium-silicate-hydrate gel, contributing to the mechanical properties and decrease in alkalinity of SWSSC. A design model for SWSSC is proposed, focusing on alkalinity, mechanical strength, and environmental benefits. This proposed model enhances application of SWSSC in construction, catering to specialized marine engineering structures, like artificial islands, harbors and offshore structures. This study contributes to a large-scale processing strategy of sediment and provides an economical and green alternative construction material for sustainable infrastructures.
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Developing green and economical low-alkalinity seawater sea sand concrete via innovative processing underground sediment
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Accepted/In Press date: 23 January 2024
e-pub ahead of print date: 7 February 2024
Published date: 13 February 2024
Identifiers
Local EPrints ID: 497907
URI: http://eprints.soton.ac.uk/id/eprint/497907
ISSN: 0959-6526
PURE UUID: 38578c59-43bf-45e7-83c9-87dc5119a9c4
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Date deposited: 04 Feb 2025 17:48
Last modified: 08 Feb 2025 03:21
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Contributors
Author:
Ao Zhou
Author:
Jialiang Chen
Author:
Kexuan Li
Author:
Tiejun Liu
Author:
Jian-Xin Lu
Author:
Dujian Zou
Author:
Ye Li
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