[3] [3] TANG W, MOHSENI E, WANG Z Y. Development of vegetation concrete technology for slope protection and greening［J］. Construction and Building Materials, 2018, 179: 605-613.

[4] [4] CALVO J L G, HIDALGO A, ALONSO C, et al. Development of low-pH cementitious materials for HLRW repositories［J］. Cement and Concrete Research, 2010, 40(8): 1290-1297.

[5] [5] FAIZ H, NG S, RAHMAN M. A state-of-the-art review on the advancement of sustainable vegetation concrete in slope stability［J］. Construction and Building Materials, 2022, 326: 126502.

[6] [6] KONG J F, WANG Z H, MENG X B, et al. Study on alkali reduction treatments and plant growth properties of planting concrete［J］. Sustainability, 2022, 14(19): 12228.

[7] [7] GANAPATHY G P, ALAGU A, RAMACHANDRAN S, et al. Effects of fly ash and silica fume on alkalinity, strength and planting characteristics of vegetation porous concrete［J］. Journal of Materials Research and Technology, 2023, 24: 5347-5360.

[8] [8] BAO X H, LIAO W Y, DONG Z J, et al. Development of vegetation-pervious concrete in grid beam system for soil slope protection［J］. Materials, 2017, 10(2): 96.

[9] [9] LEE K H, YANG K H. Development of a neutral cementitious material to promote vegetation concrete［J］. Construction and Building Materials, 2016, 127: 442-449.

[10] [10] GONG C C, ZHOU X M, DAI W Y, et al. Effects of carbamide on fluidity and setting time of sulphoaluminate cement and properties of planting concrete from sulphoaluminate cement［J］. Construction and Building Materials, 2018, 182: 290-297.

[16] [16] LI L, WU M. An overview of utilizing CO2 for accelerated carbonation treatment in the concrete industry［J］. Journal of CO2 Utilization, 2022, 60: 102000.

[18] [18] LI S, YIN J, ZHANG G. Experimental investigation on optimization of vegetation performance of porous sea sand concrete mixtures by pH adjustment［J］. Construction and Building Materials, 2020, 249: 118775.

[20] [20] XUE K W, WAN C J, XU Y W, et al. Effect of pre-hydration age on phase assemblage, microstructure and compressive strength of CO2 cured cement mortar［J］. Construction and Building Materials, 2022, 325: 126760.

[21] [21] LIU R Q, YANG Y Q, ZHAO X K, et al. Quantitative phase analysis and microstructural characterization of Portland cement blends with diatomite waste using the Rietveld method［J］. Journal of Materials Science, 2021, 56(2): 1242-1254.

[22] [22] SHAO Y X, ROSTAMI V, HE Z, et al. Accelerated carbonation of Portland limestone cement［J］. Journal of Materials in Civil Engineering, 2014, 26(1): 117-124.

[23] [23] HU L L, JIA Y S, CHEN Z, et al. An insight of carbonation-hydration kinetics and microstructure characterization of cement paste under accelerated carbonation at early age［J］. Cement and Concrete Composites, 2022, 134: 104763.

[24] [24] CHANG J, FANG Y F, SHANG X P. The role of β-C2S and γ-C2S in carbon capture and strength development［J］. Materials and Structures, 2016, 49(10): 4417-4424.

[25] [25] MONKMAN S, SARGAM Y, NABOKA O, et al. Early age impacts of CO2 activation on the tricalcium silicate and cement systems［J］. Journal of CO2 Utilization, 2022, 65: 102254.

[26] [26] ROSTAMI V, SHAO Y X, BOYD A J, et al. Microstructure of cement paste subject to early carbonation curing［J］. Cement and Concrete Research, 2012, 42(1): 186-193.

[27] [27] HE P P, SHI C J, TU Z J, et al. Effect of further water curing on compressive strength and microstructure of CO2-cured concrete［J］. Cement and Concrete Composites, 2016, 72: 80-88.

[28] [28] LIU M, HONG S X, WANG Y S, et al. Compositions and microstructures of hardened cement paste with carbonation curing and further water curing［J］. Construction and Building Materials, 2021, 267: 121724.

[29] [29] MU Y D, LIU Z C, WANG F Z, et al. Carbonation characteristics of γ-dicalcium silicate for low-carbon building material［J］. Construction and Building Materials, 2018, 177: 322-331.

[30] [30] SHTEPENKO O, HILLS C, BROUGH A, et al. The effect of carbon dioxide on β-dicalcium silicate and Portland cement［J］. Chemical Engineering Journal, 2006, 118(1/2): 107-118.