Strength recovery of thermally damaged high-performance concrete subjected to post-fire carbonation curing
Strength recovery of thermally damaged high-performance concrete subjected to post-fire carbonation curing
This study investigates the efficacy of post-fire curing using carbonation with a 20% carbon dioxide concentration and a relative humidity cycle set between 40% and 90% for restoring the mechanical properties of thermally damaged high-performance concrete (HPC) specimens containing 0%–40% silica fume. The HPC specimens were exposed to temperatures of 600, 800, and 1000 °C for 1 h, and the compressive strength recovery was measured. The microstructure, porosity, pore size distribution, and chemical composition of the HPC specimens were analyzed to explore the strength recovery mechanism. After exposure to elevated temperatures, the average compressive strength of samples without silica fume decreased by 49.2 MPa. Subsequent carbonation recuring resulted in a significant recovery of 73.9 MPa in the average compressive strength. This recovery surpassed the original strength for the samples heated to 600 and 800 °C, attributable to the filling and coalescing effects of calcium carbonate polymorphs formed through the carbonation of residual cement particles and β-C2S. The samples containing 20% silica fume exhibited the second highest average strength recovery of 34.1 MPa. However, the strength recovery for the samples with 40% silica fume exposed to 800 and 1000 °C was negligible, as the microcracks exceeding 1 μm in width had barely been restored by the carbonation of the low-calcium calcium silicates with low reactivity. Overall, this study presents an exciting future prospect for the labor and cost-effective restoration of thermally damaged concrete structures through the use of carbonation curing.
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Wang, Haodong
bd36d0d4-12de-4a21-86fe-a0aaf78ea68a
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Long, Xu
ea7d4840-feb1-49c7-bd66-9faafa29ddd0
Miah, Md Jihad
0a0c52da-9b25-44b9-a937-def203926d35
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
31 August 2023
Liu, Tiejun
07e72a65-be75-4b13-b54d-9ed949c93470
Wang, Haodong
bd36d0d4-12de-4a21-86fe-a0aaf78ea68a
Zou, Dujian
f932d3d9-b218-4268-a86e-0bb63aec1e31
Long, Xu
ea7d4840-feb1-49c7-bd66-9faafa29ddd0
Miah, Md Jihad
0a0c52da-9b25-44b9-a937-def203926d35
Li, Ye
86d13351-982d-46c3-9347-22794f647f86
Liu, Tiejun, Wang, Haodong, Zou, Dujian, Long, Xu, Miah, Md Jihad and Li, Ye
(2023)
Strength recovery of thermally damaged high-performance concrete subjected to post-fire carbonation curing.
Cement and Concrete Composites, 143.
(doi:10.1016/j.cemconcomp.2023.105273).
Abstract
This study investigates the efficacy of post-fire curing using carbonation with a 20% carbon dioxide concentration and a relative humidity cycle set between 40% and 90% for restoring the mechanical properties of thermally damaged high-performance concrete (HPC) specimens containing 0%–40% silica fume. The HPC specimens were exposed to temperatures of 600, 800, and 1000 °C for 1 h, and the compressive strength recovery was measured. The microstructure, porosity, pore size distribution, and chemical composition of the HPC specimens were analyzed to explore the strength recovery mechanism. After exposure to elevated temperatures, the average compressive strength of samples without silica fume decreased by 49.2 MPa. Subsequent carbonation recuring resulted in a significant recovery of 73.9 MPa in the average compressive strength. This recovery surpassed the original strength for the samples heated to 600 and 800 °C, attributable to the filling and coalescing effects of calcium carbonate polymorphs formed through the carbonation of residual cement particles and β-C2S. The samples containing 20% silica fume exhibited the second highest average strength recovery of 34.1 MPa. However, the strength recovery for the samples with 40% silica fume exposed to 800 and 1000 °C was negligible, as the microcracks exceeding 1 μm in width had barely been restored by the carbonation of the low-calcium calcium silicates with low reactivity. Overall, this study presents an exciting future prospect for the labor and cost-effective restoration of thermally damaged concrete structures through the use of carbonation curing.
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Accepted/In Press date: 25 August 2023
e-pub ahead of print date: 29 August 2023
Published date: 31 August 2023
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Local EPrints ID: 498380
URI: http://eprints.soton.ac.uk/id/eprint/498380
PURE UUID: ddd64afc-ae25-497a-a9ce-a2a24c126570
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Date deposited: 17 Feb 2025 17:55
Last modified: 18 Feb 2025 03:12
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Contributors
Author:
Tiejun Liu
Author:
Haodong Wang
Author:
Dujian Zou
Author:
Xu Long
Author:
Md Jihad Miah
Author:
Ye Li
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