(王贻明，王志凯，吴爱样，等.新型胶凝充填材料制备及固化机理分析.金属矿山，2018.000(006)：20-24.) [3]LAN W T,WU A X,WANG Y M,et al.Experimental study on influencing factors of the filling strength of hemihydrate phosphogypsum.Journal of HARBIN institute of Technology,2019,51(8):128-135 (兰文涛，吴爱祥，王贻明，等.半水磷石膏充填强度影响因素试验.哈尔滨工业大学学报，2019,51(8)：128-135) [4]YAN Peiyu,ZHENG Feng.Kinetics model for the hydration mechanism of cementitious materials.Journal of the Chinese ceramic society,2006,34(5):555-559. (阎培渝，郑峰.水泥基材料的水化动力学模型.硅酸盐学报，2006,34(5)：555-559.) [5]LI Linxiang,XIE Yongjiang,FENG Zhongwei,et al.Cement hydration mechanism and research methods.Concrete, 2011(06:85-89. (李林香，谢永江，冯仲伟，等.水泥水化机理及其研究方法几.混凝土，2011(06)：85-89.) [6]F Han,J Liu,P Yan.Effect of temperature on the hydration of composite binder containing slag.Journal of the Chinese ceramic society,.2016(8):1071-1080 [7]LV Quanhong,XIAO Lianzhen.Temperature Effect of Cement-Based Materials Based on Hydration Kinetics Model.Journal of Wuhan Institute of Technology,2020,42(4):434-438 (吕全红，肖莲珍.基于水化动力学模型的水泥基材料温度效应.武汉工程大学学报，202042(4)：434-438.) [8]Ulm F,Coussy O.Modeling of thermochemomechanical couplings of concrete ages.Journal of engineering mechanics,1995,121(7):785-794. 9]Suzuki M,Fukuura N,Takeda H,et al.Establishment of coupled analysis of interaction between structural deterioration and reinforcement corrosion by salt damage.Journal ofAdvanced Concrete Technology,2016,14(9):559-572. [10]Gawin D,Pesavento F,Schrefler B A.Hygro-thermo-chemo-mechanical modelling of concrete at early ages and beyond.Part I: hydration and hygro-thermal phenomena.International Journal for Numerical Methods in Engineering,2006,67(3):299-331. [11]FENG Chuqiao,YU Xiaomin,CHANG Xiaolin,et al.The Deduetion and Application of a Hydration Model for Concrete Based on Chemical Reaction Kinetics.China Rural Water and Hydropower,2019,435(01):152-157. (冯楚桥，余晓敏，常晓林，等，混凝土水化化学反应动为学模型的推导及应用).中国农村水利水电，2019,435(01)152- 157.) [12]Liu S,Wang L,Gao Y,et al.Influence of fineness on hydration kinetics of supersulfated cement[J].Thermochimica Acta,2015, 605:37-42. [13]Neusinger R,Drach V,Ebert H P,et al.Computer Simulations that Illustrate the Heat Balance of Landfills[J].International Journal of Thermophysics,2005.26(2):519-530. [14]Effect of curing temperature on cementitious property of Hemihydrate phosphogypsum[J].Chinese Journal of Engineering. doi:10.13374/.issn2095-9389.202d113.001 (王志凯，王貽明，吴爱祥，李根，李剑秋.养护温度对半水磷石膏胶凝性能影响.工程科学学报.doi:1013374iss2095 9389.20201113.00L.) [15]Liu XH,Zhang C.Chang XL,et al.Precise simulation analysis of the thermal field in mass concrete with a pipe water cooling system.Applied Phermal Engineering,2015,78:449-459 [16]YANG Xianwan.Manual for the calculation of thermodynamic data in high temperature.Beijing:Metallurgical Industry Press, 1983. (杨显万.高温水溶液热力学数据计算手册.北京：冶金工业出版社，1983.) [17]LI Xianbo.Crystal morphology control and hydration hardening properties of high strength a-hemihydrate phosphogypsum [Dissertation].Guizhou University.2019. (李显波.高强a半水磷石膏晶形调控及水化硬化性能研究[学位论文].贵州大学，2019.) [18]HONG Qingyang.Study on influence factors of rate of chemical.Guangzhou Chemical Industry,2017,17(v.45):211-212. (洪清扬.探析影响化学反应速率的因素.广州化工，2017,17(v.45):211-212.)（王贻明, 王志凯, 吴爱祥,等. 新型胶凝充填材料制备及固化机理分析. 金属矿山, 2018, 000(006):20-24.） [3] LAN W T, WU A X, WANG Y M, et al. Experimental study on influencing factors of the filling strength of hemihydrate phosphogypsum. Journal of HARBIN institute of Technology, 2019, 51(8):128-135 （兰文涛, 吴爱祥, 王贻明,等. 半水磷石膏充填强度影响因素试验. 哈尔滨工业大学学报, 2019, 51(8):128-135） [4] YAN Peiyu, ZHENG Feng. Kinetics model for the hydration mechanism of cementitious materials. Journal of the Chinese ceramic society, 2006, 34(5):555-559. （阎培渝, 郑峰. 水泥基材料的水化动力学模型. 硅酸盐学报, 2006, 34(5):555-559.） [5] LI Linxiang, XIE Yongjiang, FENG Zhongwei, et al. Cement hydration mechanism and research methods. Concrete, 2011(06):85-89. （李林香, 谢永江, 冯仲伟,等. 水泥水化机理及其研究方法[J]. 混凝土, 2011(06):85-89.） [6] F Han, J Liu, P Yan. Effect of temperature on the hydration of composite binder containing slag. Journal of the Chinese ceramic society, 2016(8):1071-1080. [7] LV Quanhong, XIAO Lianzhen. Temperature Effect of Cement - Based Materials Based on Hydration Kinetics Model. Journal of Wuhan Institute of Technology, 2020,42(4):434-438. （吕全红，肖莲珍. 基于水化动力学模型的水泥基材料温度效应. 武汉工程大学学报, 2020, 42(4):434-438.） [8] Ulm F, Coussy O. Modeling of thermochemomechanical couplings of concrete at early ages. Journal of engineering mechanics，1995,121(7):785-794． [9] Suzuki M, Fukuura N, Takeda H, et al. Establishment of coupled analysis of interaction between structural deterioration and reinforcement corrosion by salt damage. Journal of Advanced Concrete Technology, 2016,14(9):559-572． [10] Gawin D, Pesavento F, Schrefler B A. Hygro-thermo-chemo-mechanical modelling of concrete at early ages and beyond. Part I: hydration and hygro-thermal phenomena. International Journal for Numerical Methods in Engineering, 2006,67(3):299-331． [11] FENG Chuqiao, YU Xiaomin, CHANG Xiaolin, et al. The Deduction and Application of a Hydration Model for Concrete Based on Chemical Reaction Kinetics. China Rural Water and Hydropower, 2019, 435(01):152-157. （冯楚桥, 余晓敏, 常晓林,等. 混凝土水化化学反应动力学模型的推导及应用[J]. 中国农村水利水电, 2019, 435(01):152- 157.） [12] Liu S, Wang L, Gao Y, et al. Influence of fineness on hydration kinetics of supersulfated cement[J]. Thermochimica Acta, 2015, 605:37-42. [13] Neusinger R, Drach V, Ebert H P, et al. Computer Simulations that Illustrate the Heat Balance of Landfills[J]. International Journal of Thermophysics, 2005, 26(2):519-530. [14] Effect of curing temperature on cementitious property of Hemihydrate phosphogypsum[J]. Chinese Journal of Engineering. doi:10.13374/j.issn2095-9389.2020.11.13.001. （王志凯, 王贻明, 吴爱祥, 李根, 李剑秋. 养护温度对半水磷石膏胶凝性能影响. 工程科学学报. doi:10.13374/j.issn2095- 9389.2020.11.13.001.） [15] Liu XH, Zhang C, Chang XL, et al. Precise simulation analysis of the thermal field in mass concrete with a pipe water cooling system. Applied Thermal Engineering, 2015,78:449－459 [16] YANG Xianwan. Manual for the calculation of thermodynamic data in high temperature. Beijing: Metallurgical Industry Press, 1983. （杨显万. 高温水溶液热力学数据计算手册. 北京: 冶金工业出版社, 1983.） [17] LI Xianbo. Crystal morphology control and hydration hardening properties of high strength α-hemihydrate phosphogypsum [Dissertation]. Guizhou University, 2019. （李显波. 高强 α 半水磷石膏晶形调控及水化硬化性能研究[学位论文]. 贵州大学, 2019.） [18] HONG Qingyang. Study on influence factors of rate of chemical. Guangzhou Chemical Industry, 2017, 17(v.45):211-212. （洪清扬. 探析影响化学反应速率的因素. 广州化工, 2017, 17(v.45):211-212.） 录用稿件，非最终出版稿