張同生

2001年9月至2005年6月： 濟南大學，材料科學與工程專業，本科，獲學士學位；

2005年9月至2008年6月： 濟南大學，材料學專業，研究生，獲碩士學位；

2008年9月至2012年6月 ：華南理工大學，材料學專業，研究生，獲博士學位；

2012年7月至2014年9月： 華南理工大學材料科學與工程學院，博士後/助理研究員；

2014年10月至2019年8月： 華南理工大學材料科學與工程學院，副研究員；

2017年7月至2018年7月： 倫敦大學學院（UCL），訪問學者，合作導師：Julia Stegemann；

2019.10至今 華南理工大學，材料科學與工程學院，研究員，博士生導師。 ^[1] 

複合水泥與混凝土研究；

固體廢棄物建築材料資源化利用；

功能水泥基材料；

水泥工業環境影響評價。

國家自然科學基金：低氧、高CO2環境中SO2的催化氧化、快速捕獲及固化機制（主持）

十三五國家重點研究計劃子課題：“高抗蝕硅酸鹽水泥基材料組成設計與微結構調控”（主持）

國家自然科學基金：“複合水泥水化產物與未水化相對體積變形的影響機理及製備高體積穩定性複合水泥的研究”（主持）；

廣東特支計劃科技創新青年拔尖人才（主持）

廣州市珠江科技新星專項基金：“複合水泥漿體組成、結構優化設計及體積穩定性、抗裂性能改善機理”（主持）；

廣東省水利科技創新項目：“利用淤泥製備陶粒生態、淨水混凝土及其在自淨化河道中的應用”（主持）

廣東省科技計劃項目：“針對華南地區高硫石灰石生產水泥的窯內幹法脱硫技術研究”（主持）

華南理工大學—傑出青年基金：“基於體積穩定性、抗裂性能的複合水泥組成、結構優化設計”（主持）；

中國博士後科學基金特別資助：“初始堆積狀態和水化進程對複合水泥漿體變形的影響機理”（主持）；

中國博士後科學基金：“礦渣基級配複合水泥水化產物組成、結構與化學收縮關係”（主持）；

中央高校基本科研業務費：“基於體積穩定性、抗裂性能的複合水泥組成、結構優化設計”（主持）；

國家“973”計劃項目：“水泥熟料和輔助性性膠凝材料優化複合的化學和物理基礎”（參與）；

國家自然科學基金重點項目：“複合水泥材料高效應用的基礎研究”（參與）；

國家自然科學基金國際交流合作項目：“基於材料5R原則下水泥工業協同處置固廢時有毒有害組分影響的研究”（參與）。

水泥生產過程中環境影響研究：水泥窯煙氣脱硫、脱硝基本理論與技術，CO2捕集與封存研究，水泥窯協同處置廢棄物過程中重金屬的遷移轉化行為研究。

輔助性膠凝材料：工業固體廢棄物的物理、化學性質及其對水泥混凝土基本性能的影響，科學高效、環境友好地利用固體廢棄物生產水泥混凝土等建築材料。

功能建築材料：高抗蝕水泥基材料、透水淨水混凝土等。

基於上述研究，主持/參與國家自然科學基金、“973計劃”課題、國家重點研發計劃課題等國家省部級項目20餘項，在Cement and Concrete Composites、Powder Technology、Construction and Building Materials等期刊發表論文60餘篇（SCI收錄42篇），在行業刊物上發表學術論文60餘篇（SCI收錄42篇），申請/授權發明專利20餘件，研究成果獲得了多位國際同行專家的高度評價、認可和引用，累計被引1000餘次，google scholar H-index 19，研發的高性能複合水泥、高強高透水混凝土、水泥窯催化複合脱硫等研究成果得到了大規模工業化應用。 ^[1] 

代表性論文如下：

[1] A Bogush, JA Stegemann*, QZ Zhou, ZY Wang, B Zhang, TS Zhang, WS Zhang, JX Wei. Co-processing of raw and washed air pollution control residues from energy-from-waste facilities in the cement kiln. Journal of Cleaner Production, 2020, 254: 119924.

[2] XG Xie, TS Zhang*, ZY Lin, JX Wei, QJ Yu. Mixture proportion design of pervious concrete based on the relationships between fundamental properties and skeleton structures. Cement and Concrete Composites. 2020, 113: 103693.

[3] YM Yang, TS Zhang*, ZH Li, KX Zhao, JX Wei, QJ Yu. Corrosion resistance of steel bar and chloride binding capacity of cementitious materials with internal chloride: A comparative study on Portland cement, geopolymer, inter-ground and gap-graded blended cements. Journal of Thermal Analysis and Calorimetry. 2020, 139: 1903–1914.

[4] TS Zhang*, C Wu, B Li, JW Wang, C Wang, XZ Chen, JX Wei, QJ Yu*. Clarifying the decomposition process of pyrite and SO2 release in the cyclone preheater of a dry rotary cement kiln system. Journal of Cleaner Production, 2019, 241: 118422.

[5] TS Zhang*, C Wu, B Li, JW Wang, R Ravat, XZ Chen, JX Wei, QJ Yu*. Linking the SO₂ emission of cement plants to the sulfur characteristics of their limestones: A study of 80 NSP cement lines in China. Journal of Cleaner Production, 2019, 220: 200-211.

[6] TS Zhang*, WL Tian, YQ Guo, A Bogush, E Khayrulina, JX Wei, QJ Yu. The volumetric stability, chloride binding capacity and stability of the Portland cement-GBFS pastes: An approach from the viewpoint of hydration products. Construction and Building Materials. 2019, 205: 357-367.

[7] YQ Guo,TS Zhang*, WL Tian, JX Wei, QJ Yu. Physically and chemically bound chlorides in hydrated cement pastes: A comparison study of the effects of silica fume and metakaolin,Journal of Materials Science, 2019, 54(3): 2152-2169.

[8] XG Xie,TS Zhang*, YM Yang, ZY Lin, JX Wei, QJ Yu. Maximum paste coating thickness without voids clogging of pervious concrete and its relationship to the rheological properties of cement paste.Construction and Building Materials, 2018, 168: 732–746.

[9] YQ Guo,TS Zhang*, XY Liu, WL Tian, P Chen, JX Wei, QJ Yu. The pore fillability of cementitious materials and its application in predicting compressive strength of gap-graded blended cements.Construction and Building Materials, 2018, 168: 805–817.

[10] SL Liu,TS Zhang*, YQ Guo, JX Wei, QJ Yu. Effects of SCMs particles on the compressive strength of micro-structurally designed cement paste: Inherent characteristic effect, particle size refinement effect, and hydration effect.Powder Technology, 2018, 330: 1–11.

[11] B Zhang, A Bogush, JX Wei*,TS Zhang, WT Xu, QJ Yu. Influence of sulfur on the fate of heavy metals during clinkerization.Construction and Building Materials, 2018, 182: 144–155.

[12] P Gao,TS Zhang, JX Wei*, QJ Yu. Evaluation of RRSB distribution and lognormal distribution for describing the particle size distribution of graded cementitious materials.Powder Technology, 2018, 331: 137–145.

[13] YQ Guo,TS Zhang*, JX Wei, QJ Yu, SX Ouyang. Evaluating the distance between particles in fresh cement paste based on the yield stress and particle size.Construction and Building Materials, 2017, 142: 109–116.

[14] PH Gao, JX Wei,TS Zhang, J Hu, QJ Yu. Modification of chloride diffusion coefficient of concrete based on the electrical conductivity of pore solution.Construction and Building Materials, 2017, 145: 361–366.

[15] B Zhang, A Bogush, JX Wei*,TS Zhang, J Hu, FX Li, QJ Yu. Reversible carbon dioxide capture at high temperatures by tetraethylenepentamine acetic acid and polyethylene glycol mixtures with high capacity and low viscosity.Fuel & Energy, 2017, 31(4): 4237–4244.

[16] SR Yu, B Zhang, JX Wei*,TS Zhang, QJ Yu, WS Zhang. Effects of chlorine on the volatilization of heavy metals during the co-processing of sewage sludge.Waste Management, 2017, 62: 204–210.

[17] YM Yang, ZH Li,TS Zhang, JX Wei, QJ Yu*. Bond-slip behavior of Basalt Fiber Reinforced Polymer (BFRP) bar in concrete subjected to simulated marine environment: Effects of BFRP bars size, corrosion age, and concrete strength.International Journal of Polymer Science, 2017: 1–9.

[18] YQ Guo,TS Zhang*, JX Wei, QJ Yu. SX Ouyang. Evaluating the distance between particles in fresh cement paste based on the yield stress and particle size,Construction and Building Materials, 2017,142: 109–116.

[19] W Zhu, JX Wei, FX Li,TS Zhang, Y Chen, J Hua, QJ Yu. Understanding restraint effect of coarse aggregate on the drying shrinkage of self-compacting concrete.Construction and Building Materials, 2016, 114:458–463.

[20] W Zhu, Y Chen, FX Li,TS Zhang, J Hu, JX Wei*, QJ Yu. Design and preparation of high elastic modulus self-compacting concrete for pre-stressed mass concrete structures.Journal of Wuhan University of Technology-Materials Science Edition, 2016, 31(3): 563–573.

[21] ZM Huang,TS Zhang*,ZY Wen. Proportioning and characterization of Portland cement-based ultra-lightweight foam concretes.Construction and Building Materials,2015, 79: 390–396.

[22] SH Yin, YF Yang,TS Zhang*, GF Guo, F Yu. Effect of carbonic acid water on the degradation of Portland cement paste: Corrosion process and kinetics.Construction and Building Materials, 2015,91: 39–46.

[23] ZH Li,TS Zhang, J Hu, Y Tang, YF Niu, JX Wei, QJ Yu. Characterization of reaction products and reaction process of MgO–SiO₂–H₂O system at room temperature.Construction and Building Materials, 2014, 61:252–259.

[24] P Gao,TS Zhang, RF Luo, JX Wei, QJ Yu*. Improvement of autogenous shrinkage measurement for cement paste at very early age: Corrugated tube method using non-contact sensors.Construction and Building Materials, 2014, 55:57–62.

[25]TS Zhang, XY Liu, JX Wei, QJ Yu*. Influence of preparation method on the performance of ternary blended cements.Cement and Concrete Composites, 2014, 52: 18–26.

[26]TS Zhang, P Gao, RF Luo, JX Wei, QJ Yu*. Volumetric deformation of gap-graded blended cement pastes with large amount of supplementary cementitious materials.Construction and Building Materials, 2014, 54 339–347.

[27]TS Zhang, P Gao, RF Luo, YQ Guo, JX Wei, QJ Yu*. Measurement of chemical shrinkage of cement paste: Comparison study of ASTM C1608 and an improved method.Construction and Building Materials, 2013, 48: 662–669.

[28]TS Zhang, P Gao, PH Gao, JX Wei, QJ Yu*. Effectiveness of novel and traditional methods to incorporate industrial wastes in cementitious materials–an overview.Resources, Conservation and Recycling, 2013, 74: 134–143.

[29]TS Zhang, QJ Yu*, JX Wei, PP Zhang, CC Gong. Effect of simulative pore solution on the hydration kinetics of ground granulated blast furnace slag.Advances in Cement Research, 2013, 24(5): 283–290.

[30]TS Zhang, QJ Yu, JX Wei*, JX Li. Investigation on mechanical properties, durability and micro-structural development of steel slag blended cements.Journal of Thermal Analysis and Calorimetry, 2012, 110(2): 633–639.

[31]TS Zhang, QJ Yu*, JX Wei, PP Zhang, PX Chen. Improvement of surface cementitious properties of coarse fly ash by dehydration and rehydration processes.Journal of Thermal Analysis and Calorimetry, 2012, 109(1): 265–271.

[32]TS Zhang, QJ Yu, JX Wei*, P Gao, PP Zhang. Study on optimization of hydration process of blended cement.Journal of Thermal Analysis and Calorimetry, 2012, 107(2): 489–498.

[33]TS Zhang, QJ Yu*, JX Wei, P Gao, PX Chen, J Hu. Micro-structural development of gap-graded blended cement paste containing high amount of supplementary cementitious materials.Cement and Concrete Composites, 2012, 34(9): 1024–1032.

[34]TS Zhang, QJ Yu*, JX Wei, PP Zhang. Efficient utilization of cementitious materials to produce sustainable blended cement.Cement and Concrete Composites, 2012, 34(5): 692–699.

[35]TS Zhang, QJ Yu, JX Wei*, PP Zhang. A new gap-graded particle size distribution and resulting consequences on properties of blended cement.Cement and Concrete Composites, 2011, 33(5): 543–550.

[36]TS Zhang, QJ Yu*, JX Wei, PP Zhang, PX Chen. A gap-graded particle size distribution for blended cements: Analytical approach and experimental validation.Powder Technology, 2011, 214(2): 259–268.

[37]TS Zhang, QJ Yu*, JX Wei, JX Li, PP Zhang. Preparation of high performance blended cement and reclamation of iron concentrate from basic oxygen furnace steel slag.Resources, Conservation and Recycling, 2011, 56(1): 48–55.

[38]TS Zhang, QJ Yu*, JX Wei, PP Zhang. Effects of size fraction on composition and fundamental properties of Portland cement.Construction and Building Materials, 2011, 25(7): 3038–3043.

[39]TS Zhang, QJ Yu, JX Wei*, PP Zhang. Effect of size fraction on composition and pozzolanic activity of high calcium fly ash.Advances in Cement Research, 2011, 23(6): 299–307.

[40]TS Zhang, QJ Yu*, JX Wei, PP Zhang, S Li. Effect of size fraction of ground granulated blast furnace slag on its strength contribution and hydraulic activity.Advanced Science Letters, 2011, 4(3): 1286–1291.

[41] JX Li, QJ Yu, JX Wei*,TS Zhang. Structural characteristics and hydration kinetics of modified steel slag.Cement and Concrete Research, 2011, 41(3): 324–329.

[42]TS Zhang, FT Liu, SQ Liu, ZH Zhou, X Cheng*. Factors influencing the properties of a steel slag composite cement.Advances in Cement Research, 2008, 20(3): 145–150.

[43] 餘其俊, 林秋旺, 李方賢, 韋江雄,張同生, 胡捷. 硅酸鈣板－纖維增強泡沫混凝土複合牆板的受壓性能.華南理工大學學報, 2017, 45(9): 88-95.

[44] 楊永民, 李兆恆,張同生, 殷素紅, 韋江雄, 陳曉文, 餘其俊. 活性氧化鎂補償無機聚合物漿體收縮的作用機制.華南理工大學學報, 2017, 45(9): 103-110.

[45]張同生, 李斌, 餘其俊, 陳新智, 段明子. 煙氣複合脱硫技術最新進展.水泥, 2017, 7: 52-56.

[46] 楊永民,張同生, 陳澤鵬, 陳理達. 模擬壩體温升的養護制度對輕燒MgO混凝土力學性能的影響研究.膨脹劑與膨脹混凝土, 2015/02

[47] 張賓, 陳陽, 韋江雄,張同生, 餘其俊. 三維數字圖像相關法及其在水泥基材料變形研究中的應用. 電子顯微學報, 2015, 34(6): 521-529.

[48] 蘇登成, 夏毅, 沈東, 賀希,張同生. 高温乾燥環境中C20和C30混凝土的體積穩定性研究. 水泥工程, 2015, 5: 81-85.

[49]張同生, 劉向陽, 韋江雄, 餘其俊*. 水泥熟料與輔助性膠凝材料優化匹配的基礎研究進展（I）——物理效應.水泥, 2014. (7): 7–13.

[50]張同生, 劉向陽, 韋江雄, 餘其俊*. 水泥熟料與輔助性膠凝材料優化匹配的基礎研究進展（II）——化學效應.水泥, 2014. (8): 8–14.

[51] 劉向陽,張同生, 張平平, 韋江雄, 餘其俊. 低活性粉煤灰表面膠凝性能改善研究.硅酸鹽通報, 2014/07.

[52] 王玲, 蘇登成, 夏毅,張同生. 利用循環流化牀灰渣製備控制性低強度材料的研究.水泥工程2014/04.

[53] 蘇登成, 顏炳波, 王玲, 謝華,張同生. 大摻量輔助膠凝材料自密實混凝土的試驗研究.水泥工程, 2013/1.

[54] 劉仁越, 王珊,張同生, 劉玉中, 蘇登成. 消石灰、無水石膏與石灰石粉對礦渣水泥性能的影響.水泥. 2009/8.

[55] 蘇登成, 唐興國, 劉仁越, 徐振寧,張同生. 鋼渣活性激發技術研究進展. 中國水泥, 2009/4.

[56]張同生, 劉福田*, 李義凱, 周宗輝, 程新. 活性激發劑對鋼渣膠凝材料強度影響的研究.建築材料學報, 2008, 11(4): 469–474.

[57]張同生, 劉福田*, 周宗輝, 李義凱. 鋼渣粉煤灰複合水泥的研究.濟南大學學報, 2008, 22(2): 174–177.

[58]張同生, 劉福田*, 王建偉, 李義凱, 周宗輝, 程新. 鋼渣安定性與活性激發的研究進展.硅酸鹽通報, 2007, 26(5): 980–984.

[59] 張同生, 劉福田, 劉鑫. 溶膠-凝膠法制備合金表面耐腐蝕塗層的研究進展. 山東冶金, 2007, 3: 4-7.