[1] [1] SHI J Y, LIU B J, WU X A, et al. Evolution of mechanical properties and permeability of concrete during steam curing process[J]. J Build Eng, 2020, 32: 101796.

[2] [2] CHANG Y, LI X D, MASANET E, et al. Unlocking the green opportunity for prefabricated buildings and construction in China[J]. Resour Conserv Recycl, 2018, 139: 259-261.

[3] [3] NIE S, ZHOU J, YANG F, et al. Analysis of theoretical carbon dioxide emissions from cement production: methodology and application[J]. J Clean Prod, 2022, 334: 130270.

[4] [4] ZHANG J J, YE C B, TAN H B, et al. Potential application of Portland cement-sulfoaluminate cement system in precast concrete cured under ambient temperature[J]. Constr Build Mater, 2020, 251: 118869.

[5] [5] LIU B J, XIE Y J, LI J. Influence of steam curing on the compressive strength of concrete containing supplementary cementing materials[J]. Cem Concr Res, 2005, 35(5): 994-998.

[6] [6] BENAMMAR B, MEZGHICHE B, GUETTALA S. Influence of atmospheric steam curing by solar energy on the compressive and flexural strength of concretes[J]. Constr Build Mater, 2013, 49: 511-518.

[7] [7] AHMAD M R, CHEN B, HAQUE M A, et al. Multiproperty characterization of cleaner and energy-efficient vegetal concrete based on one-part geopolymer binder[J]. J Clean Prod, 2020, 253: 119916.

[8] [8] CHEN L, ZHENG K R, XIA T B, et al. Mechanical property, sorptivity and microstructure of steam-cured concrete incorporated with the combination of metakaolin-limestone[J]. Case Stud Constr Mater, 2019, 11: e00267.

[9] [9] HAN Jianguo, YAN Peiyu, HOU Weihong. J Chin Ceram Soc, 2016, 44(8): 1120-1125.

[10] [10] HAN Jianguo, YAN Peiyu, HOU Weihong. J Chin Ceram Soc, 2016, 44(11): 1543-1551.

[11] [11] YANG G, XU D S, HU Z L, et al. Tensile and compressive creep of UHSM with CaO-based expansive agent[J]. Constr Build Mater, 2022, 355: 129122.

[12] [12] GARCíA CALVO J L, CARBALLOSA P, PEDROSA F, et al. Microstructural phenomena involved in the expansive performance of cement pastes based on type K expansive agent[J]. Cem Concr Res, 2022, 158: 106856.

[13] [13] ZENG L P, ZHAO S A, WANG W, et al. Accelerated early age hydration of cement pastes blended with sulphoaluminate expansive agent[J]. J Adv Concr Technol, 2021, 19(6): 655-667.

[14] [14] CAO F Z, YAN P Y. The influence of the hydration procedure of MgO expansive agent on the expansive behavior of shrinkage-compensating mortar[J]. Constr Build Mater, 2019, 202: 162-168.

[15] [15] ZHANG J A. Recent advance of MgO expansive agent in cement and concrete[J]. J Build Eng, 2022, 45: 103633.

[16] [16] HAN J G, JIA D, YAN P Y. Understanding the shrinkage compensating ability of type K expansive agent in concrete[J]. Constr Build Mater, 2016, 116: 36-44.

[17] [17] NIE S, ZHANG Q W, LAN M Z, et al. Fundamental design of low-carbon ordinary Portland cement-calcium sulfoaluminate clinker-anhydrite blended system[J]. Cem Concr Compos, 2023, 139: 105053.

[18] [18] LI B, WU C, LI Y, et al. Expansive behavior of high-strength self-stressing and self-compacting concrete: experimental study and analytical model[J]. Constr Build Mater, 2022, 353: 129080.

[19] [19] YAN P Y, QIN X. The effect of expansive agent and possibility of delayed ettringite formation in shrinkage-compensating massive concrete[J]. Cem Concr Res, 2001, 31(2): 335-337.

[20] [20] YAN P Y, QIN X, YANG W Y, et al. The semiquantitative determination and morphology of ettringite in pastes containing expansive agent cured in elevated temperature[J]. Cem Concr Res, 2001, 31(9): 1285-1290.

[21] [21] ZHANG D, LI V C, ELLIS B R. Ettringite-related dimensional stability of CO2-cured Portland cement mortars[J]. ACS Sustain Chem Eng, 2019, 7(19): 16310-16319.

[22] [22] MEHTA P K. Expansion characteristics of calcium sulfoaluminate hydrates[J]. J Am Ceram Soc, 1967, 50(4): 204-208.

[23] [23] CHAUNSALI P, MONDAL P. Influence of calcium sulfoaluminate (CSA) cement content on expansion and hydration behavior of various ordinary Portland cement-CSA blends[J]. J Am Ceram Soc, 2015, 98(8): 2617-2624.

[24] [24] LIU Jie, ZHANG Luosong, SUN Tao, et al. J Build Mater, 2019, 22(4): 656-665.

[25] [25] LI C Y, SHANG P R, LI F L, et al. Shrinkage and mechanical properties of self-compacting SFRC with calcium-sulfoaluminate expansive agent[J]. Materials, 2020, 13(3): 588.

[26] [26] GANGA V, SENTHIL SELVAN S. Influence of expansive cement on rheological, strength performance and morphological characteristics of self-compacting concrete[J]. Constr Build Mater, 2023, 368: 130407.

[27] [27] YEUNG J S K, YAM M C H, WONG Y L. 1-Year development trend of concrete compressive strength using Calcium Sulfoaluminate cement blended with OPC, PFA and GGBS[J]. Constr Build Mater, 2019, 198: 527-536.

[28] [28] YANG Lin, YAN Yun, HU Zhihua, et al. Cement, 2012(7): 7-10.

[29] [29] BOLA?OS-VáSQUEZ I, TRAUCHESSEC R, TOBóN J I, et al. Influence of the ye’elimite/anhydrite ratio on PC-CSA hybrid cements[J]. Mater Today Commun, 2020, 22: 100778.

[30] [30] WINNEFELD F, MARTIN L H J, MüLLER C J, et al. Using gypsum to control hydration kinetics of CSA cements[J]. Constr Build Mater, 2017, 155: 154-163.

[31] [31] ZHANG Y, ZHANG Z H, SHI C Q, et al. Development of a new calcium sulfoaluminate (synthetic ye'elimite) blended PII 52.5 cement[J]. Adv Cem Res, 2017, 29(9): 373-386.

[32] [32] DENG M, TANG M S. Formation and expansion of ettringite crystals[J]. Cem Concr Res, 1994, 24(1): 119-126.

[33] [33] SHAIKH F U A, SUPIT S W M. Chloride induced corrosion durability of high volume fly ash concretes containing nano particles[J]. Constr Build Mater, 2015, 99: 208-225.

[34] [34] MüLLAUER W, BEDDOE R E, HEINZ D. Sulfate attack expansion mechanisms[J]. Cem Concr Res, 2013, 52: 208-215.