杨政险，1976年3月生，安徽淮南人，教授，博士生导师，福建省“闽江学者”特聘教授。博士毕业于荷兰代尔夫特理工大学土木工程与地质科学学院（代尔夫特理工大学是世界顶级理工大学之一，QS2020世界大学最新综合排名全球50，土木工程学科排名全球第2），师从混凝土耐久性及腐蚀防护领域国际知名学者R.B. Polder，J.M.C Mol（Corrosion Science 期刊主编）和C. Andrade教授，在荷兰攻读博士期间获中国国家海外优秀留学生奖，是2011年“中欧青年交流年”中国驻荷兰使馆受邀中方代表。2007年起先后工作学习于美国、荷兰及西班牙等欧美知名高校和国家研究院。2017年以 “学科带头人” 引进至5848vip威尼斯电子游戏工作，担任5848vip威尼斯学术委员会委员、5848vip威尼斯电子游戏滨海基础设施腐蚀与防护研究中心主任、先进土木工程材料福建省高校工程研究中心主任。 中国建筑学会工程诊治与运维分会委员，国家建筑工程技术研究中心建筑工程与材料测试技术论坛专委会委员，福建省力学学会常务理事，国内建材学科核心期刊 《建筑材料学报》编委，瑞士学术期刊《Catalysts》专刊主编。

主持和参与包括美国和中国国家自然科学基金在内的科研项目30余项，获批总经费达350多万美元。已在Advanced Materials、Cement and Concrete Research、Cement and Concrete Composites等国际知名学术期刊发表第一或通讯作者SCI论文80余篇（多为中科2区和Q1区），已授权专利18项（其中发明12项目，PCT国际专利1项，实用新型6项），参编3本书籍章节和3项行业和地方标准；10多次参加国际大会并作报告，第一和通讯作者国际会议论文20多篇。谷歌学术统计近5年发表论文总被引用2200余次，单篇最高被引370余次，h因子26。现指导博士、研究生30余名。

杨政险博士在土木工程材料及耐久性领域，特别是新型低碳环保高性能海洋工程材料的设计与研发、海工混凝土多尺度微观结构性能以及钢筋混凝土的腐蚀防护和对策方面取得了一定的研究成果。开发了一类新的基于氨基酸改性的环保混凝土智能添加剂，并首次应用海洋等高盐环境中钢筋混凝土结构的腐蚀防护；自主设计开发了“钢筋混凝土腐蚀三联检测法及实时软件监测系统”；该新型测试法被荷兰皇家应用科学组织(TNO)资深科学家、荷兰代尔夫特理工大学教授R.B. Polder评价为“杨/Delft法”。该法同时得到国际混凝土耐久性研究领域权威专家，国际腐蚀工程师协会（NACE）Willis Rodney Whitney 奖获得者、RILEM前主席，西班牙建筑科学院前院长 C. Andrade 教授的高度评价，并受邀赴西班牙访问合作。

海洋工程材料的腐蚀和生物污损控制，包括：新型低碳环保高性能海洋工程材料的设计与研发；滨海基础设施耐久性及服役寿命预测及评估；钢筋的腐蚀机理及海工混凝土的劣化和生物污损控制。

土木工程新材料、新技术及智能混凝土，包括：有机/无机杂化材料分子设计及功能化、自修复混凝土、光催化及纳米科技在建筑材料和环保领域的应用；水泥水化动力学、混凝土微观结构及界面多尺度性能表征。

绿色低碳3D打印智能建造，包括：新型环保低碳水泥基材料3D打印快速成型机理与关键技术；绿色3D打印材料与结构的性能测试与评价。

固体废弃物在建材领域的资源化综合利用，包括：冶金废渣，淤泥、建筑渣土等大宗工业固废及废弃植物纤维等多种农业废弃物、生物质在水泥混凝土工业中的应用研究。

与欧洲及美国多个知名高校有多年的科研合作和联合培养及研究生交换计划。支持学生在硕士或者博士期间以申请国家留学基金委或者福建省研究生留学计划以及课题组项目资金配套支持的方式国外交流学习1-2年。

招收结构工程，高性能建筑材料方向博士以及结构工程、土木工程、道路交通工程与灾害防治、建筑材料与结构工程方向硕士；常年招生土木工程方向博士后及研究助理。

Li, W., Dong, B., Yang, Z., Xu, J., Chen, Q., Li, H., Xing, F., Jiang, Z*.  Recent advances in intrinsic self-healing cementitious materials. Advanced Materials, 2018, 1705679:1-9.（IF: 32.086，中科院1区）

Zhang, Y., Wu, K., Yang, Z.*, Ye, G*. A reappraisal of the ink-bottle effect and pore structure of cementitious materials using intrusion-extrusion cyclic mercury porosimetry. Cement and Concrete Research, 2022, 161:106942.（IF: 11.958，中科院1区）

Zhang, Y., Yang, Z.*, Ye, G*. Dependence of unsaturated chloride diffusion on the pore structure in cementitious materials. Cement and Concrete Research, 2020, 127:105919.（IF: 11.958，中科院1区）

Yang, Z.*, Polder, R., Mol, J.M.C., Andrade, C. The effect of two types of modified Mg-Al hydrotalcites on reinforcement corrosion in cement mortar. Cement and Concrete Research, 2017, 100:196-202.（IF: 11.958，中科院1区）

Yang, Z.*, Xu, J., Wang, W., Zhang, Y., Yang, L. Surface properties and de-polluting performance of a photocatalytic coating incorporating novel core@ shell nanospheres for cementitious substrate. Cement and Concrete Composites, 2023, 139:105036.（IF: 9.930，中科院1区）

Zhang, Y., Fang, Y., Shen, Y., Yang, Z.*, Wu, K*. Chloride penetration and binding behavior in unsaturated alkali-activated slag mortars. Cement and Concrete Composites, 2023, 140:105098.（IF: 9.930，中科院1区）

Yang, Z.*, Fischer, H., Polder, R. Laboratory investigation of the influence of two types of modified hydrotalcites on chloride ingress into cement mortar. Cement and Concrete Composites, 2015, 58:105-113.（IF: 9.930，中科院1区）

Yang, Z.*, Fischer, H., Polder, R. Synthesis and characterisation of modified hydrotalcites and their ion exchange characteristics in chloride-rich simulated concrete pore solution. Cement and Concrete Composites, 2014, 47(3):87-93.（IF: 9.930，中科院1区）

Yang, Z.*, Hollar, J., He, X., and Shi, X. A self-healing cementitious composite using oil core/silica gel shell microcapsules. Cement and Concrete Composites, 2011, 33(4):506-512.（IF: 9.930，中科院1区）

Li, K., Zhang, Y. Lu, L., Li, Y., Yang, Z.*, Niu, Y.* Effect of pretreated cow dung fiber on mechanical and shrinkage properties of cementitious composites. Journal of Cleaner Production, 2022, 375:131374.（IF: 11.072，中科院1区）

Li, H., Wang, Z., Sun, R., Huang, F. Wen, J., Lu, L., Yang, Z.*. Effect of different lithological stone powders on properties of cementitious materials. Journal of Cleaner Production, 2021, 289:125820.（IF: 11.072，中科院1区）

Niu, D., Xie, X. Zhang, Z., Niu, Y., Yang, Z.*. Influence of binary waste mixtures on road performance of asphalt and asphalt mixture. Journal of Cleaner Production, 2021, 298:126842. （IF: 11.072，中科院1区）

Niu, D., Zhang, Z., Gao, Y.*, Li, Y., Yang, Z., Niu, Y. Effect of pretreated cow dung fiber on rheological and fatigue properties of asphalt binder. Cellulose, 2023, 30(6):3773-3791. （IF: 6.123，中科院1区）

Lu, L., Yang, Z.*, Lin, Y., Dong, S. Partial replacement of manufactured sand with homologous granite powder in mortar: The effect on porosity and capillary water absorption. Construction and Building Materials, 2023, 376:131031.（IF: 7.693，中科院1区）

Wei, Z., Chen, B.*, Gu, K., Yang, Z. Study of untreated phosphogypsum as a fine aggregate for magnesium oxysulfate cement. Construction and Building Materials, 2023, 365:130040.（IF: 7.693，中科院1区）

Yang, Z., Shi, P., Zhang, Y., Li, Z*. Effect of superabsorbent polymer introduction on properties of alkali-activated slag mortar. Construction and Building Materials, 2022, 340:127541.（IF: 7.693，中科院1区）

Fang, L., Zhou, J., Yang, Z.*, Yuan, Q., Que., Y. Interaction between cement and asphalt emulsion and its influences on asphalt emulsion demulsification, cement hydration and rheology. Construction and Building Materials, 2022, 329:127220.（IF: 7.693，中科院1区）

Xu, J., Yang, H. Yang, Z.*, Huang, M., Zhang, Y., Yang, C. The effect of TiO2@CoAl-LDH nanosphere on early hydration of cement and its photocatalytic depollution performance under UV-visible light. Construction and Building Materials, 2022, 319:126277.（IF: 7.693，中科院1区）

Zhang, Y., Ye, G., Yang, Z.*. New insight into long-term chloride transport in unsaturated cementitious materials: role of degree of water saturation. Construction and Building Materials, 2020, 238:117677.（IF: 7.693，中科院1区）

Zhang, Y., Ye, G., Yang, Z.*. Pore size dependent connectivity and ionic transport in saturated cementitious materials. Construction and Building Materials, 2020, 238:117680.（IF: 7.693，中科院1区）

Chen, Y., Ji, T., Yang, Z.*, Zhan W. Zhang Y. Sustainable use of ferronickel slag in cementitious composites and the effect on chloride penetration resistance. Construction and Building Materials, 2020, 240:117969.（IF: 7.693，中科院1区）

Yang, Y., Ji, T., Su, W., Yang, B., Zhang, Z., Yang, Z.* Photocatalytic NOX abatement and self-cleaning performance of cementitious composites with g-C3N4 nanosheets under visible light. Construction and Building Materials, 2019, 225:120-131.（IF: 7.693，中科院1区）

Niu, D., Chen, H., Kim, R., Sheng, Y., Geng, J., Xiong, R., Yang, Z.* Damage assessment of asphalt concrete with composite additives at the FAM-coarse aggregate interfacial zone. Construction and Building Materials, 2019, 198:587-596.（IF: 7.693，中科院1区）

Yang, Z., Zhang, Y., Shi, X. Impact of nanoclay and carbon microfiber in combating the deterioration of asphalt concrete by non-chloride deicers. Construction and Building Materials, 2018, 160:514-525.（IF: 7.693，中科院1区）

He, J., Du, S., Yang, Z.*, Shi, X*. Laboratory investigation of graphene oxide suspension as a surface sealer for cementitious mortars. Construction and Building Materials, 2018, 162:65-79.（IF: 7.693，中科院1区）

Yang, Y., Ji, T., Lin, X., Chen, C, Yang, Z.*.biogenic sulfuric acid corrosion resistance of new artificial reef concrete. Construction and Building Materials, 2018, 158:33-41.（IF: 7.693，中科院1区）

Lv, L., Zhang, H., Schlangen, E., Yang, Z.*, Xing, F*. Experimental and numerical study of crack behaviour for capsules-based self-healing cementitious materials. Construction and Building Materials, 2017, 156:219-229.（IF: 7.693，中科院1区）

Lv, L., Yang, Z*., Chen, G., Han, N., Schlangen, E., Zhu, G., Xing, F*. Synthesis and Characterization of a New Polymeric Microcapsule and Feasibility Investigation in Self-healing Cementitious Materials. Construction and Building Materials, 2016, 105: 487-495.（IF: 7.693，中科院1区）

Yang, Z.*, Fischer, H., Cerezo, J., Mol, J.M.C., Polder, R. Aminobenzoate modified Mg-Al hydrotalcites as a novel smart additive of reinforced concrete for anticorrosion applications. Construction and Building Materials, 2013, 47, 1436-1443.（IF: 7.693，中科院1区）

Yang, Z., Shi, X., Creighton, A. T., Peterson, M. M. Effect of styrene-butadiene rubber latex on the chloride permeability and microstructure of portland cement mortars. Construction and Building Materials, 2009, 23(6):2283-2290.（IF: 7.693，中科院1区）

Wang, W., Ye, Y., Li, G., Yang, Z*., Duan, J., Sun, J., Yan, Y. High-efficiency photocathodic protection performance of novel MnIn2S4/TiO2 n-n heterojunction films for Q235 carbon steel in chloride containing simulated concrete pore solution. Journal of Alloys and Compounds, 2023, 941:168957.（IF: 6.371，中科院2区）

Wang, W., Yang, Z.*, Li, G., Zhang, Y., Cao, W., Xu, J., Zheng, R. Drastic promotion of the photocathodic protection property of TiO2 nanotube films decorated with n-type CuInS2 nanoparticles. Journal of Alloys and Compounds, 2021, 89: 161895（IF: 6.371，中科院2区）

Yang, Z., Xiong, X., Chen, S., Briseghella, B., Marano, G. C., Zhang, Y*. Effect of fineness on the hydration and microstructure of cementitious materials with high-volume steel slag and blast furnace slag. Journal of Building Engineering, 2023, 72:106682. （IF: 7.144，中科院2区）

Yang, Z., Shi, P. Zhang, Y., Li, Z*. Influence of liquid-binder ratio on the performance of alkali-activated slag mortar with superabsorbent polymer. Journal of Building Engineering, 2022, 48:103934（IF: 7.144，中科院2区）

Xu, J., Yang, Z.*, Chen, S., Wang, W., Zhang, Y. Compatibility and photocatalytic capacity of the novel core@shell nanospheres in cementitious composites. Catalysts, 2022, 12:1574. （IF: 4.501，中科院3区）

Huang, M., Yang, Z.*, Lu, L., Xu, J., Wang, W., Yang, C. The preparation of gc3n4/coal-ldh nanocomposites and their depollution performances in cement mortars under UV-visible light. Catalysts, 2022, 12(4):443.（IF: 4.501，中科院3区）

Liu, X., Yang, Z.*, Li, K., Briseghella, B., Marano, G.C., Xu, J. Visible light antibacterial potential of cement mortar incorporating Cu-ZnO/gC3N4 nanocomposites. RSC advances, 2023, 13(14):9448-9456.（IF: 4.036，中科院3区）

Zhu, S., Ji, T., Yang, B., Yang, Z.* Preparation and characterization of PEG/surface-modified layered double hydroxides as a new shape-stabilized phase change material. RSC Advances, 2019, 9(41):23435-23443.（IF: 4.036，中科院3区）

Zhu, S., Ji, T., Niu, D., Yang, Z.*. Investigation of PEG/mixed metal oxides as a new form-stable phase change material for thermoregulation and improved UV ageing resistance of bitumen. RSC Advances, 2020, 10: 44903-44911（IF: 4.036，中科院3区）

Niu, D., Zhang, Z., Meng, J., Yang, Z*, Jing, R., Liu, X., Sheng, Y. Surface modification of steel slag aggregate for engineering application in asphalt mixture. Buildings, 2023, 13(1):16.（IF: 3.324，中科院3区）

Zhang, Y., Yang, B., Yang, Z.*, Ye, G. Ink-bottle effect and pore size distribution of cementitious materials identified by pressurization-depressurization cycling mercury intrusion porosimetry. Materials. 2019, 12:1454.（IF：3.748，中科院3区）

Zhang, Y., Ouyang, X.*, Yang, Z.* Microstructure-based relative humidity in cementitious system due to self-desiccation. Materials. 2019, 12:1214.（IF：3.748，中科院3区）

Xu, Q., Tao, Ji., Gao, S., Yang, Z.*. Characteristics and applications of sugar cane bagasse ash waste in cementitious materials. Materials, 2019, 12(1):39.（IF：3.748，中科院3区）

Yang, Z., Hollar, J., and Shi, X. Surface-sulfonated polystyrene microspheres improve crack resistance of carbon microfiber-reinforced portland cement mortar. Journal of Materials Science, 2010, 45(13):3497-3505（IF: 4.682，中科院3区）

Yang, Z.*, Fischer, H., Cerezo, J., Mol, J.M.C., Polder, R. Modified hydrotalcites for improved corrosion protection of reinforcing steel in concrete-preparation, characterization and assessment in alkaline chloride solution. Materials and Corrosion, 2016, 67(7):721-738（IF: 2.097，中科院3区）

Yang, Z.*, Fischer, H., Polder, R. Modified Hydrotalcites as a new emerging class of smart additive of reinforced concrete for anti-corrosion applications: a literature review. Materials and Corrosion, 2013, 64(12):1066-1074 （IF: 2.097，中科院3区）

Lin, J., Zhang, Y., Yang, Z*. A review of recent advances in alkali-activated materials from silica-rich wastes derived sodium silicate activators. Journal of Advanced Concrete Technology, 2023, 21(3):189-203. （IF: 2.459，中科院4区）

Zhuo, W., Yan, Q., Yang, Z.*, Lin, S., Lin, K., He, F. Chloride penetration in coastal concrete structures: Field investigation and model development. Advances in Materials Science and Engineering, 2019: 4537283 （IF: 2.098，中科院4区）

Han, B.*, Yang, Z.*, Shi, X., Yu, X. Transport properties of carbon-nanotube/cement composite. Journal of Materials Engineering and Performance, (co-first author), 2013, 22(1): 184-189（IF: 2.019，中科院4区）

Yang, Z., Hollar, J., Shi, X., and He, X. Laboratory Assessment of A Self-healing Cementitious Composite. Transportation Research Record: Journal of the Transportation Research Board, 2010, 2142: 9-17（IF: 1.560，中科院4区）

Yang, Z*, Polder, R, Mol, J.M.C., Modified Hydrotalcites as Chloride Scavengers and Inhibitor Release Agents for Concrete Application. HERON, 2017, 62(2): 61-83.

张勇, 方宇迟, 徐轶扬, 夏雨, 杨政险*. 双电层对碱矿渣胶凝材料氯离子传输的影响研究[J].建筑材料学报, 2023:1-11.（EI收录）

张勇, 方宇迟, 沈颖, 杨政险*. 不同饱和度碱矿渣砂浆中氯离子传输试验研究, 建筑材料学报, 2022，25(12): 1219-1224.（EI收录）

杨政险, 李慷, 张勇, 王艳, 牛荻涛. 天然植物纤维预处理方法对水泥基复合材料性能的影响研究进展, 硅酸盐学报，2022, 50(2), 39.（EI收录）

陈尚鸿, 林佳福, 杨政险*, 张勇, 熊晓立. 钢渣-矿渣透水混凝土力学性能的试验研究[J].硅酸盐通报, 2023:1-14.（北大核心）

施鹏, 杨政险*, 张勇, 陈卓睿. 不同淤泥掺量免烧砖在碱粉煤灰矿渣体系下的性能研究[J]. 新型建筑材料， 2020, 47(09): 40-44.（北大核心）

Yang, Z., Hong, R., Lu, L. Detection method for determining content of chloride ions in sea sand, PCT/CN2020/102548.

杨政险, 辛东升, 林旭健. 一种以石灰-碳酸钠为激发剂的单组份碱激发胶凝材料：ZL201810045798.X.

杨政险, 洪荣灿, 卢林. 一种确定海砂中氯离子含量的检测方法：ZL201910802795.0.

杨政险, 卢林, 黄梦崖. 一种具有光催化作用的人工粗骨料及其制备方法：ZL202110056394.2.

杨政险, 卢林, 王文成. 一种抗菌水泥砂浆及其制备和应用方法：ZL202110056602.9.

杨政险, 卢林, 张勇. 一种抗菌粗骨料及其制备方法：ZL202110057180.7.

杨政险, 卢林, 王文成. 一种抗菌水泥混凝土及其制备方法：ZL202110056603.3.

杨政险, 卢林, 张勇. 一种抗菌沥青混凝土及其制备方法：ZL202110057202.X.

王心晨, 杨政险, 阳灿. 一种含硼碳氮的光催化水泥砂浆及其制备方法：ZL202110055931.1.

王心晨, 杨政险, 阳灿. 一种光催化水泥混凝土及其制备方法：ZL202110055943.4.

张勇, 杨政险, 卢林. 一种确定水泥基材料不同尺度孔隙连通性的方法： ZL202110160767.0.

王文成, 林镇坤, 杨政险.一种氯离子响应智能缓蚀微胶囊及其制备方法：ZL202210595911.8.