施锦杰
发布时间:2017-09-08   浏览次数:1586
 基 本 信 息

姓名:施锦杰

性别:

党派:中共党员

职称:教授、硕导

联系方式:Emailjinjies@126.com jinjies@seu.edu.cn

          手机/微信号:138514027350


研究方向:

1. 合金化耐蚀钢筋的耐蚀机理与工程应用(金属材料方向)

2. 碱激发胶凝材料体系的耐久性(土木工程材料方向)

3. 土木工程智能自修复防腐体系开发(高分子材料方向)

 个 人 简 介

个人简介

 1983年出生,江苏海门人。

河海大学无机非金属材料专业(本科) 2002.9 – 2006.7

东南大学材料科学与工程学院材料学专业(导师:孙院士。硕博连读:2006.9-2011.12

东南大学电子科学与工程学院(博士后:2011.12-2013.11

东南大学材料科学与工程学院讲师2013.12-2017.6

东南大学材料科学与工程学院副教授2017.4-至今)

期间于2017.9-2018.8 挂职江阴市华士镇党委副书记(江苏省科技镇长团)

  

主持的项目:

[1]国家自然科学青年基金钢筋-混凝土界面区缺陷对钢筋腐蚀行为的影响与修复方法研究51208098” 2013/01-2015/12,结题。

[2]国家自然科学面上基金海洋环境下低合金钢筋在碱激发矿渣混凝土中的耐腐蚀性与腐蚀机理51678144” 2017/01-2020/12,在研。

[3]江苏省自然科学基金面上项目碱激发胶凝材料中耐腐蚀钢筋的电化学行为与腐蚀产物研究BK 201614202016/07-2019/06,在研。

[4]中国博士后科学基金特别资助“荷载与环境作用下耐蚀钢筋混凝土的劣化机理与服役寿命(2013T60490

[5]博士后科学面上基金低合金耐蚀钢筋在混凝土中的耐蚀机理与服役寿命预测2012M520975

[6]2012年东南大学博士后重点资助计划A类资助耐蚀钢筋混凝土结构的耐蚀机理与服役寿命预测

[7]高性能土木工程材料国家实验室2011年开放基金课题“氯盐与碳化对混凝土中钢筋锈蚀影响的差异性研究2011CEM002

[8]江苏省土木工程材料重点实验室2012年开放基金课题“氯盐与碳化对模拟混凝土孔溶液中耐蚀钢筋的钝化与腐蚀行为的影响2012CEM04

[9]东大-欧维姆预应力工程技术联合研究中心项目“后张预应力混凝土体系的电隔离性能研究”

参与的项目:

[1]国家重点基础研究发展计划973项目(2009CB623200)“环境友好现代混凝土的基础研究”

[2]国家重点基础研究发展计划973项目(2015CB655100)“严酷环境下混凝土材料与结构长寿命的基础研究”

[3]国家自然科学基金中英联合项目(51461135001)“生态低碳高耐久碱激发混凝土科学设计方法与应用基础研究”

[4]科技部中日政府间联合项目(2016YFE0118200)“基于海绵城市建设的多路径资源再生混凝土技术与应用”

[5]国家“863”计划项目(2008AA030704)“高速铁路用钢筋混凝土研究”

[6]交通部西部交通项目(2006ZB12)“跨江海大型桥梁结构混凝土劣化性能与耐久性对策措施的研究”

  

期刊论文:(包括Corrosion Science 1篇,Cement and Concrete Composites 3篇,ASCE Journal of Materials in Civil Engineering 5篇,Construction and Building Materials 5篇, International Journal of Minerals, Metallurgy, and Materials 3篇,European Journal of Environmental and Civil Engineering 1篇,金属学报2篇,物理化学学报1篇,硅酸盐学报 5篇,建筑材料学报 3篇等

1)一作与通讯SCI论文(21篇)

[1]Shi J J (施锦杰)*, Ming J, Sun W.Electrochemical performance of reinforcing steel in alkali-activated slag extract in the presence of chlorides. Corrosion Science, 2018, 133, 288-299. (IF=4.862)

[2]Shi J J (施锦杰)*, Ming J, Zhang Y M, Jiang J Y. Corrosion products and corrosion-induced cracks of low-alloy steel and low-carbon steel in concrete. Cement and Concrete Composites, 2018, 88, 121-129 (IF=4.660)

[3]Shi J J (施锦杰)*, Ming J, Sun W. Electrochemical behaviour of a novel alloy steel in alkali-activated slag mortars. Cement and Concrete Composites, 2018, 92, 110-124 (IF=4.660)

[4]Shi J J (施锦杰)*, Sun W. Effects of phosphate on the chloride-induced corrosion behavior of reinforcing steel in mortars. Cement and Concrete Composites, 2014, 45: 166-175. (IF=4.660)

[5]Shi J J (施锦杰)*, Sun W, Jiang J Y, Zhang Y M. Influence of chloride concentration and pre-passivation on the pitting corrosion resistance of low-alloy reinforcing steel in simulated concrete pore solution. Construction and Building Materials, 2016, 111: 805-813. (IF=3.485)

[6]Shi J J (施锦杰)*, Ming J. Influence of defects at the steel-mortar interface on the corrosion behavior of steel. Construction and Building Materials, 2017, 136: 118-125. (IF=3.485)

[7]Shi J J (施锦杰)*, Ming J, Sun W, Zhang Y M. Corrosion performance of reinforcing steel in concrete under simultaneous flexural load and chlorides attack. Construction and Building Materials, 2017, 149: 315-326. (IF=3.485)

[8]Shi J J (施锦杰)*, Ming J, Sun W. Passivation and chloride-induced corrosion of a duplex alloy steel in alkali-activated slag extract solutions. Construction and Building Materials, 2017, 155: 992-1002. (IF=3.485)

[9]Shi J J (施锦杰)*, Geng G Q. Electrochemical behavior of fine-grained steel in alkaline solutions in the presence of chlorides. ASCEJournal of Materials in Civil Engineering, 2017, 29(7): 0401703901-0401703911. (IF=1.763)

[10]Shi J J (施锦杰)*, Wang D Q, Ming J, Sun W. Long-term electrochemical behavior of low-alloy steel in simulated concrete pore solution with chlorides. ASCEJournal of Materials in Civil Engineering, 2018, 30(4): 0401804201-0401804211. (IF=1.763)

[11]Shi J J (施锦杰)*, Ming J, Sun W. Accelerated corrosion behavior of steel in concrete subjected to sustained flexural loading using electrochemical methods and X-ray computed tomography. ASCEJournal of Materials in Civil Engineering, 2018, 30(7):0401813101-0401813112 (IF=1.763)

[12]Shi J J (施锦杰)*, Ming J, Sun W. Influence of surface condition on the electrochemical behavior of alloy steel in saturated Ca(OH)2 solution. ASCEJournal of Materials in Civil Engineering, 2018, 30(9): 0401821201- 0401821212  (IF=1.763)

[13]Shi J J (施锦杰)*, Wang D Q, Ming J, Sun W. Passivation and pitting corrosion behavior of a novel alloy steel (00Cr10MoV) in simulated concrete pore solution. ASCEJournal of Materials in Civil Engineering, 2018, 30(10): 0401823201-0401823212 (IF=1.763)

[14]Shi J J (施锦杰)*, Sun W. Electrochemical and analytical characterization of three corrosion inhibitors of steel in simulated concrete pore solutions. International Journal of Minerals, Metallurgy, and Materials, 2012, 19(1): 38-47. (IF=1.261)

[15]Shi J J (施锦杰)*, Ming J. Influence of mill scale and rust layer on the corrosion resistance of low-alloy steel in simulated concrete pore solution. International Journal of Minerals, Metallurgy, and Materials, 2017, 24(1): 64-74. (IF=1.261)

[16]Shi J J (施锦杰)*, Ming J. Liu X. Pitting corrosion resistance of a novel duplex alloy steel in alkali-activated slag extract in the presence of chloride ions. International Journal of Minerals, Metallurgy, and Materials, 2017, 24(10): 1134-1144. (IF=1.261)

[17]Shi J J (施锦杰)*, Geng G Q, Ming J. Corrosion resistance of fine-grained rebar in mortars designed for high-speed railway construction. European Journal of Environmental and Civil Engineering, 2018: 22(5): 562-577. (IF=1.290)

[18]Shi J J (施锦杰)*, Sun W, Geng G Q. Influence of carbonation on the corrosion performance of steel HRB335 in simulated concrete pore solution. Acta Metall Sin, 2011, 47(1): 17-24. (IF=0.704)

[19]Shi J J (施锦杰)*, Sun W, Geng G Q. Corrosion resistances of passive films on low-carbon rebar and fine-grained rebar in alkaline media. Acta Metall Sin, 2011, 47(4): 449-454.(IF=0.704)

[20]Shi J J (施锦杰)*, Sun W. Effect of benzotriazole as corrosion inhibitor for reinforcing steel in cement mortar. Acta Physico-Chimica Sinica , 2011, 27(6): 1457-1466. (IF=0.846)

[21]Ming J, Shi J J (施锦杰)*, Sun W. Effect of mill scale on the long-term corrosion resistance of a low-alloy reinforcing steel in concrete subjected to chloride solution. Construction and Building Materials, 2018, 163: 508-517. (IF=3.485)

  

2)一作Ei论文(15篇)

[1]施锦杰,明静,王丹芊,孙伟. 大气预锈对混凝土模拟液中低合金钢筋腐蚀行为的影响. 建筑材料学报(Ei), 2017, 20(2): 180-185.

[2]施锦杰, 邓晨皓, 张亚梅. 钢筋在碱激发矿渣砂浆中的早期腐蚀行为. 建筑材料学报(Ei), 2016, 19(6):969-975.

[3]施锦杰, 孙伟. 弯曲荷载与氯盐耦合作用下混凝土中钢筋锈蚀程度评估. 硅酸盐学报(Ei), 2010, 38(7):1201-1208

[4]施锦杰, 孙伟. 混凝土中钢筋锈蚀研究现状与热点问题分析. 硅酸盐学报(Ei), 2010, 38(9): 1753-1764

[5]施锦杰, 孙伟. 矿物掺合料与钢筋表面状态对砂浆中钢筋锈蚀的影响.硅酸盐学报(Ei), 2011, 39(1): 54-62

[6]施锦杰, 孙伟. 用电化学阻抗谱与X射线CT研究混凝土中钢筋的腐蚀行为. 硅酸盐学报(Ei), 2011, 39(10): 127-133

[7]施锦杰, 孙伟. 混凝土中钢筋腐蚀速率模型研究进展. 硅酸盐学报(Ei), 2012, 40(4): 620-630

[8]施锦杰, 孙伟. 氯离子电迁移作用下饱和Ca(OH)2溶液中钢筋的锈蚀行为. 东南大学学报(Ei), 2010, 40(6): 1298-1303

[9]施锦杰, 孙伟, 耿国庆. 恒电流脉冲法研究钢筋在模拟混凝土孔溶液中的锈蚀行为. 北京科技大学学报(Ei), 2011, 33(6): 727-733

[10]施锦杰, 孙伟, 耿国庆, 蒋金洋. 电化学方法研究混凝土模拟液中细晶粒钢的耐蚀性. 北京科技大学学报(Ei), 2011, 33(12): 1471-1477

[11]施锦杰, 孙伟, 耿国庆. 模拟混凝土孔溶液对钢筋钝化的影响. 建筑材料学报(Ei), 2011, 14(4): 452-458

[12]施锦杰, 孙伟. 电迁移加速氯离子传输作用下混凝土中钢筋锈蚀研究. 东南大学学报(Ei), 2011, 41(5): 1042-1047

[13]施锦杰, 孙伟. 苯并三唑对模拟混凝土孔溶液中钢筋的缓蚀作用. 功能材料(Ei), 2010,12(41): 2147-2150

[14]Shi J J*, Sun W. Effect of sulfate ions on the corrosion behavior of steel in concrete using electrochemical techniques. Advanced Materials Research (Ei), 2011, 163-167: 3049-3054

[15]Shi J J*, Sun W. Influence of cover porosity on steel corrosion in cement-based materials. Advanced Materials Research (Ei), 2011, 163-167: 3042-3048


会议论文:

[1]Shi, J. J., Sun W, Zhang Q.Q. Influence of cover zone pore structures and steel cement interface properties on the corrosion of steel in cement based materials. EUROCORR2009, 2009. 9, Nice, France.

[2]Shi, J. J., Sun W. Corrosion behavior of pre-rusted and pre-passivated steel in mortar. Service Life Design, 2010.10, Delft, the Netherlands.

[3]Shi, J. J., Sun W. Steel corrosion monitoring in ordinary Portland concrete and high performance concrete subjected to chloride and sulfate attack. The 7th international symposium on cement and concrete, 2010. 5, Jinan, China.

[4]Shi, J. J.e, Sun W. Characterisation of the steel corrosion in simulated concrete pore solution considering the effect of accelerated chloride ingress. The 7th international symposium on cement and concrete, 2010. 5, Jinan, China.

[5]Shi, J. J., Sun W, Influence of phosphate on chloride-induced corrosion behavior of reinforcing steel in mortars. The 2nd International Conference on Microstructural-related Durability of Cementitious Composites (Microdurability). 2012, 4, Amsterdam, the Netherlands.

[6]Shi, J. J., Sun W, Jiang J. Y. Effects of chlorides on the pitting corrosion behavior of low-alloyed steel in simulated concrete pore solutions. Fifth International Conference on Construction Materials Performance, Innovations, and Structural Implications (ConMat’15), 2015.8, Whistler, BC, Canada.

[7]Shi, J. J., Sun W, Jiang J. Y, Ma H. Effects of chloride concentration on the pitting resistance of 10%Cr corrosion-resistant steel in simulated concrete pore solutions. The 14th International Congress on the Chemistry of Cement (ICCC), 2015.10, Beijing China.

[8]Shi, J. J., Wang D. Q., Ming J, Chen H.S. Electrochemical Behavior of 00Cr10MoV Steel in Alkali-activated Slag Extract. 3rd International RILEM Conference on Microstructure Related Durability of Cementitious Composites, 24-26 October 2016, Nanjing, China.

[9]施锦杰,明静,王丹芊,蒋金洋,孙伟6%Cr 钢筋在混凝土模拟液中的氯盐点蚀行为, 第八届全国腐蚀大会, 2015.11, 厦门。

[10]Shi, J. J., Ming J., Zhang Y.M., Jiang J.Y. and Sun W. Effect of mill scale on the corrosion resistance of low-alloy steel in saturated Ca(OH)2 solution containing chlorides. 37th Cement and Concrete Science Conference, 11-12 September 2017, University College London, UK.

[11]Ming J, Shi, J. J, Sun W. The long-term electrochemical performance and rust distribution of reinforcing steels in concrete. The 2nd ACF Symposium Innovations for Sustainable Concrete Infrastructures, 23-25 November 2017. Chiang Mai, Thailand.

  

发明专利:

1. 施锦杰. 一种模拟混凝土孔溶液中钢筋锈蚀测试的腐蚀池 - 201510664328.8;105203449B (授权)


获奖情况:

2016东南大学青年教师教学竞赛三等奖

2016东南大学教学工作一等奖

2017国立中泰三等奖教金

  

迄今为止,已为Corrosion Science, Electrochimica Acta, Construction and Building Materials, Journal of Cleaner Production, European Journal of Environmental and Civil Engineering, Materials Science and Engineering: B, Materials and Structures,南京理工大学学报,中国海洋工程,应用基础与工程科学学报,长沙理工大学学报(自然科学版)等国内外期刊审稿。并被Construction and Building Materials期刊评为2017年度优秀审稿人。


欢迎有土木工程、金属材料、建筑材料、高分子材料以及电化学背景的同学报考研究生。