The influence of new and old mortar matrix, carbon curing, and water curing on the performance and damage evolution of CO2-injected model concrete

Xingchang Cheng; Yuan Cao; Qiong Liu; Chang Sun; Vivian W. Y. Tam; Amardeep Singh

doi:10.1007/s44242-025-00097-3

Low-carbon Materials and Green Construction ›› 2026, Vol. 4 ›› Issue (1) :1 DOI: 10.1007/s44242-025-00097-3

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The influence of new and old mortar matrix, carbon curing, and water curing on the performance and damage evolution of CO₂-injected model concrete

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Abstract

This study investigated the working performance of mortar after CO₂ injection and mixing. Three curing regimes — carbonation curing, water curing, and combined carbonation-water curing (WC) — were employed to identify the most effective environment and method for curing and strength enhancement. The influence of recycled aggregate strength on the damage evolution of recycled concrete was analyzed using model concrete specimens and the digital image correlation (DIC) technique. The results indicate that specimens subjected to combined carbonation-water curing exhibited the lowest porosity, with a reduction of 1.7%–2.0% compared with those under carbonation curing alone, which showed the highest porosity. Moreover, the damage evolution process demonstrated clear regularity, and the strain development exhibited a relatively predictable trend. The higher the water-to-cement ratio of the CO₂-injected mixed mortar, the lower its fluidity, with reductions ranging from 7.3% to 13.3%. Conversely, a lower water-to-cement ratio resulted in a greater loss of workability after CO₂ injection mixing. In addition, a pronounced strength difference between the new and old mortar matrices led to strain concentration within the old mortar region.

Keywords

CO₂-injection mixing / Carbonation curing / Damage evolution / Model concrete

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Xingchang Cheng, Yuan Cao, Qiong Liu, Chang Sun, Vivian W. Y. Tam, Amardeep Singh. The influence of new and old mortar matrix, carbon curing, and water curing on the performance and damage evolution of CO₂-injected model concrete. Low-carbon Materials and Green Construction, 2026, 4(1): 1 DOI:10.1007/s44242-025-00097-3

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Gupta S, Kashani A, Mahmood AH, Han T. Carbon sequestration in cementitious composites using biochar and fly ash – Effect on mechanical and durability properties. Construction and Building Materials, 2021, 291 123363

[2]	Dwivedi A, Gupta S. Influence of carbon sequestration in natural clay on engineering properties of cement-lime stabilized soil mortars. Development Built Environment, 2023, 16 100270

[3]	Meng D, Unluer C, Yang EH, Qian S. Recent advances in magnesium-based materials: CO2 sequestration and utilization, mechanical properties and environmental impact. Cement and Concrete Composites, 2023, 138 104983

[4]	Kaliyavaradhan SK, Ling TC, Mo KH. CO2sequestration of fresh concrete slurry waste: Optimization of CO2uptake and feasible use as a potential cement binder. Journal of CO2 Utilization, 2020

[5]	Zhang T, Hu K, Chen Y, Lv Y, Xue X, Qiao P. A wet carbonation enhancement approach to synergistic preparation of alkali-activated artificial aggregates from waste concrete powder and ground granulated blastfurnace slag. Construction and Building Materials, 2025

[6]	Chen C, Long WJ, Feng GL, Hu KY, Luo QL, Xiong C, Wang YC, Zhong AN. Mechanistic insights into CO2 nanobubble-enhanced short-term wet carbonation of recycled concrete fines. Construction and Building Materials, 2025

[7]	Das KK, Wu X, Noh G, Lee JH, Jang JG. Effect of acid attack coupled with elevated temperatures on carbonation-cured calcium sulfoaluminate and ordinary Portland cement paste. Case Studies in Construction Materials, 2025, 23 e05150

[8]	Xu J, Yang Z, Zheng Z, Nicolaides D, Zhang Y, Marano GC, Briseghella B. Influence of core-shell nanospheres on the carbonation development of cement mortars and its mechanism: Synergistic effect of hydration and early CO2 uptake. Cement and Concrete Composites, 2026, 165 106310

[9]	Senff L, Barbetta PA, Repette WL, Hotza D, Paiva H, Ferreira VM, Labrincha JA. Mortar composition defined according to rheometer and flow table tests using factorial designed experiments. Construction and Building Materials, 2009, 23: 3107-3111

[10]	Li Y, Zeng X, Yao X, Long G, Liew KM. Coupled effect of paraffin and carbonation curing on the electrical resistivity of cement-based materials: Mechanisms and quantitative contributions. J. Build. Eng., 2025, 111 113581

[11]	Xiang J, Guo Y, Song Y, Ren B, Qiu J. Carbon sequestration and microstructure of cemented paste backfill prepared with bio-wet carbonated basic oxygen furnace slag. Construction and Building Materials, 2025

[12]	Shang X, Chen Y, Qi Y, Chang J, Yang J, Qu N. Comparative life cycle environmental assessment of recycled aggregates concrete blocks using accelerated carbonation curing and traditional methods. Construction and Building Materials, 2023

[13]	Lyu S, Zou Q, Quan J, Zhang N, Hu K, Gui L, Yu W, Liang S, Duan H, Yang J. From laboratory to industrial scale: How to evaluate the carbon mineralization of cement and cement-based materials. Environmental Impact Assessment Review, 2026, 117 108171

[14]	Liang C, Li B, Guo MZ, Hou S, Wang S, Gao Y, Wang X. Effects of early-age carbonation curing on the properties of cement-based materials: A review. Journal of Building Engineering, 2024, 84 108495

[15]	Gu Y, Mohseni E, Farzadnia N, Khayat KH. An overview of the effect of SAP and LWS as internal curing agents on microstructure and durability of cement-based materials. Journal of Building Engineering, 2024, 95 109972

[16]	Belayneh GB, Kim N, Seo J, Kim H, Park S, Son HM, Park S. Effect of fly ash on hydration and carbonation of carbonation-cured Portland cements. Journal of CO2 Utilization, 2024

[17]	Wang S, Ren S, Tao W, Wan X, Qiu K, Liang C, Yin Y, Guo C. Investigation on the influence of early carbonation curing on the mechanical strength and microstructure of pervious concrete with recycled aggregates and PC-CSA binders. Construction and Building Materials, 2025, 495 143638

[18]	Bogoviku, L., & Waldmann D. (2022). Experimental investigations on the interfacial bond strength of the adhered mortar paste to the new mortar paste in a recycled concrete matrix. Constr. Build. Mater. 347. https://doi.org/10.1016/j.conbuildmat.2022.128509.

[19]	Fu Z, Zhu H, Guo Z. Differences in microscopic properties of two major interfacial transition zones in interface between new and old concrete. Materials Letters, 2025, 391 138471

[20]	Liang C, Wang S, Cai Z, Yin Y, Gao Y, Guo MZ, Wang X, Ma Z. Effects of CO2 curing methods on frost resistance and mechanical properties of recycled aggregate concrete. Case Studies in Construction Materials, 2024, 20 e02973

[21]	Liu Q, Cheng X, Sun C, Jin C, Tam VWY. Impact of carbonization and aggregate properties on modeled recycled concrete: Mechanical characteristics, stress concentration and damage evolution. Construction and Building Materials, 2025

[22]	Ding Y, Zhang Y, Zhao Y, Zhang M, Tong J, Zhu L, Guo S. Impact of pre-soaked lime water carbonized recycled fine aggregate on mechanical properties and pore structure of 3D printed mortar. Journal of Building Engineering, 2024, 89 109190

[23]	Zuo W, Zhao X, Luo J, He Z, Zhao J. Investigating the impact of carbonation curing concentrations on the mechanical properties and microstructure of recycled concrete. Journal of Building Engineering, 2024

[24]	Lin L, Xie M, Li X, Zheng K, Wang J, Yu K, Wang Y, Xing F, Bai Y. Carbonation of cement-based materials under different conditions: From multi-characterizations to mechanism exploration. Construction and Building Materials, 2025

[25]	Xu, L., Jiang, L., Shen, L., Gan, L., Dong, Y., & Su, C. (2023). Adaptive hierarchical multiscale modeling for concrete trans-scale damage evolution. Int. J. Mech. Sci. 241. https://doi.org/10.1016/j.ijmecsci.2022.107955.

[26]	Monkman, S., Macdonald, M., Hooton, R. D., & Sandberg, P. (2016). Properties and durability of concrete produced using CO₂ as an accelerating admixture. Cement and Concrete Composites, 74, 218–224.

[27]	Rostami V, Shao Y, Boyd AJ, He Z. Microstructure of cement paste subject to early carbonation curing. Cement and Concrete Research, 2012, 42: 186-193

[28]	Ding Y, Zhang Y, Zhao Y, Zhang M, Tong J. Impact of pre-soaked lime water carbonized recycled fine aggregate on mechanical properties and pore structure of 3D printed mortar. Journal of Building Engineering, 2024

[29]	Xu, L., Wang, J., Huang, R., Li, B., Ran, B., & Hu, X. (2024). Investigations on micro-mechanical properties of the ITZs between recycled aggregates and recycled cement paste. Construction and Building Materials, 450.

[30]	Qingyin, T., Haoran, G., Heping, Z., Dongshuai, H., Muhan, W., Yue, Z., Zhenxing, D., & Pan, W. (2025). Molecular insights into enhancing bonding and erosion resistance in recycled aggregate concrete ITZ through carbonation. Journal of Building Engineering, 110.