师资队伍

唐晓(教授)

作者:审核:发布者:张秀良发布时间:2022-10-12浏览次数:3388

»姓名:唐晓

»系属:材料科学与加工系

»学位:博士

»职称:教授

»专业:材料科学与工程

»导师类别:博导/硕导

»电子邮箱:tangxiao@upc.edu.cn

»联系电话:13583238389

»网站:

»通讯地址:山东省青岛市黄岛区长江西路66

»概况:

唐晓,教授,博导,中国腐蚀与防护学会理事,中国腐蚀与防护学会腐蚀电化学及测试方法专委会副主任,中国海洋与湖沼学会化学分会理事,中国化工学会二氧化氯专家组成员,《中国腐蚀与防护学报》编委。主要从事海洋大气腐蚀及监检测技术研究,即针对海洋大气腐蚀、钢筋混凝土腐蚀、电化学工程等多相多界面复杂体系发展新型电化学测试方法和调控技术。突破极薄液膜体系测试瓶颈,揭示了大气腐蚀动力学规律;创建了浮式阻抗钢筋锈蚀无损检测技术,突破了结构健康诊断行业难题。近年来,主持国家自然科学基金项目2项,省部级课题10余项,获省部级科技奖励3项。

 ◎研究方向

1.海洋大气腐蚀

2.钢筋混凝土腐蚀无损检测

3.电化学工程(金属燃料电池、无机盐电催化)

 ◎教育经历

  1. 1996.09-2000.07,武汉大学,环境化学,学士

  2. 2000.09-2003.07,中国科学院海洋研究所,海洋腐蚀与防护,硕士

  3. 2003.09-2006.07,中国科学院海洋研究所,海洋腐蚀与防护,博士

  4. 2005.05-2005.11  香港浸会大学,电化学,联合培养博士

 ◎工作经历

  1. 2006.07-2009.05,中国海洋大学,材料科学与工程,博士后

  2. 2007.06-2008.06,加拿大卡尔加里大学,管道工程,博士后

  3. 2009.06-至今,中国石油大学(华东),材料科学与工程,副教授,教授

  4. 2018.01-2019.01,美国佛罗里达大学,电化学工程,访问学者

 ◎纵向项目

12023.01-2027.06 静水压力下****海洋腐蚀,**重点项目课题,60万,主持,在研

22020.01-2023.12 动态液滴与纯铁界面局部电极过程动力学及耦合机制(项目编号51971246),国家自然科学基金面上项目,72万,主持,结题

32020.12-2022.12 船舶与海洋工程防腐涂层腐蚀失效可视化检测技术(项目编号ZX20220227),青岛市西海岸新区源头创新科技专项,20万,主持,结题

42016.10-2018.12,燃煤锅炉烟气二氧化氯深度脱硫脱硝技术及装备(项目编号:2016GSF117031),山东省重点研发计划项目,15万,主持,结题。

52015.01-2019.12,天然气液化系统硫回收装置研制(工信部联装[2014]499号),工信部海洋工程装备科研项目,1450万,技术负责人,结题

62007.01-2010.12 微液滴来源及其与海洋大气腐蚀相关性(项目编号40706031),国家自然科学基金青年项目,18万,主持,结题

 ◎横向项目

12023.01-2025.12 腐蚀缺陷监检测成套技术开发,恩迪检测技术(青岛)有限公司,86万,主持,在研

22023.01-2024.12 实华公司码头防腐蚀本质安全研发项目,山东港口集团,34万,主持,在研

32022.07-2023.12 高活性铝合金牺牲阳极材料优选改进研究,胜利油田技术检测中心,41万,主持,结题

42020.01-2022.07 陵水25区块油套管防腐技术研究,中海油海南分公司,80万,主持,结题

 ◎教改项目

  1. 2021.01-2023.01,材料腐蚀电化学测试技术教学案例库建设(SDYAL20035),山东省教学项目,主持,结题。

 ◎主讲课程

  1. 本科生课程:《现代材料学》(全英语)、《电化学保护原理及技术》、《无损检测技术》

  2. 研究生课程:《材料腐蚀电化学测试技术》、《腐蚀电化学研究方法》

 ◎获奖情况

  1. 中国石油和化工自动化行业优秀科技著作一等奖(2/4),2021

  2. 青岛市科技进步二等奖(1/5),2022

  3. 中国石油和化学工业联合会科技进步二等奖(1/9),2023

 ◎论文

[1] Xiao Tang, Juanjuan Li, Yuan Wu et al., Electrochemical Formation Mechanism of Micro-droplets on Pure Iron, Frontiers in Chemistry, 9(2021): 610738

[2] X. Tang, C. Ran, M.E. Orazem, et al., Local electrochemical characteristics of pure iron under a saline droplet I : Effect of droplet size on electrochemical distribution, Electrochim. Acta. 354 (2020): 136633.

[3] X. Tang, C. Ran, M.E. Orazem, et al., Local electrochemical characteristics of pure iron under a saline droplet II : Local corrosion kinetics, Electrochim. Acta. 354 (2020): 136631.

[4] X. Tang, C. Ma, X. Zhou, X. Lyu, Q. Li, Y. Li, Atmospheric corrosion local electrochemical response to a dynamic saline droplet on pure iron, Electrochemistry Communications, 101(2019):28-34.

[5] J.S. Wang, X. Tang*, Y. Li, X.Q. Qiu, Observation and micro-electrochemical characterisation for micro-droplets in initial marine atmospheric corrosion, Corros. Eng. Sci. Technol. 51 (2016) 308-312.

[6] X. Tang, Y.F. Cheng, Quantitative characterization by micro-electrochemical measurements of the synergism of hydrogen, stress and dissolution on near-neutral pH stress corrosion cracking of pipelines, Corros. Sci. 53 (2011) 2927-2933.

[7] X. Tang, Y.F. Cheng, Micro-electrochemical characterization of the effect of applied stress on local anodic dissolution behavior of pipeline steel under near-neutral pH condition, Electrochim. Acta. 54 (2009) 1499-1505.

[8] X. Tang, L. Y. Xu, and Y. F. Cheng, Electrochemical corrosion behavior of X-65 steel in the simulated oil–sand slurry. II: Synergism of erosion and corrosion, Corrosion Science 50.5 (2008): 1469-1474.

[9] C. Zhong, X. Tang, Y.F. Cheng, Corrosion of steel under the defected coating studied by localized electrochemical impedance spectroscopy, Electrochim. Acta. 53 (2008) 4740-4747.

[10] J.W. Qiu, X. Tang, C. Zheng, Y. Li, Y. Huang, Copper complexation by fulvic acid affects copper toxicity to the larvae of the polychaete Hydroides elegans, Mar. Environ. Res. 64 (2007) 563-573.

[11] A. Q. Fu, X. Tang, and Y. F. Cheng, Characterization of corrosion of X70 pipeline steel in thin electrolyte layer under disbonded coating by scanning Kelvin probe, Corrosion Science, 51.1 (2009): 186-190.

[12] Xiao Tang, Yuzhi Zhang, Meng Liu, and Yan Li, Boundary element method (BEM) analysis for galvanic corrosion of hot dip galvanized steel immersed in seawater, Journal of Materials Sciences and Technology 25, 02 (2009): 194-198.

[13] X. Tang, Y.F. Cheng, Localized dissolution electrochemistry at surface irregularities of pipeline steel, Appl. Surf. Sci. 254 (2008) 5199-5205.

[14] D. Wang, X. Tang, Y. Qiu, F. Gan, G.Z. Chen, A study of the film formation kinetics on zinc in different acidic corrosion inhibitor solutions by quartz crystal microbalance, Corros. Sci. 47 (2005) 2157-2172.

 ◎专利

1)美国专利:THREE-ELECTRODE ARRAY LOCAL ELECTROCHEMICAL INFORMATION TESTING SYSTEM AND TESTING METHOD (US11333624B2)

2)唐晓,张博文,仇性启,李焰,一种浮式条件下天然气硫回收反应装置,专利号:ZL201710231093.2

3)唐晓、李焰、李亚东、马超然,一种电化学测试系统,专利号:ZL201810013803.9

4)唐晓,李强,李焰,一种多相流冲刷局部腐蚀测试装置,专利号:ZL201310116589.7

5)唐晓,李强,李焰,油井采油装备腐蚀控制器及采用该控制器的抽油杆,专利号:ZL201310008699.1

6)唐晓,李肖蔚,李焰,天然气脱硫用络合铁催化剂的复合再生装置及方法,专利号:ZL201410195059.0

7)唐晓,刘杰,李肖蔚,李焰,天然气硫回收及催化剂再生装置及方法,专利号:ZL201410254862.7

8)唐晓,李焰,一种镀层材料氢渗透性能评价方法及其专用双电解池,专利号:ZL200610046426.6

9)唐晓,马超然,李焰,吕晓蕾,三电极阵列局部电化学信息测试系统及测试方法,专利号:ZL201710319384.7



» NameTANG Xiao

» DepartmentMaterials Science

» DegreePhD

»Title: Professor

»Major: Materials Science and Engineering

»Mentor category: Doctoral supervisor, Master's supervisor

» Emailtangxiao@upc.edu.cn

»Telephone+86-13583238389

» Website

»Address: No. 66 Changjiang West Road, Huangdao District, Qingdao City, Shandong Province

»Overview:

TANG Xiao, Professor, Doctoral Supervisor, Director of the Chinese Society for Corrosion and Protection, Deputy Director of the Corrosion Electrochemistry and Testing Methods Committee of the Chinese Society for Corrosion and Protection, Director of the Chemistry Branch of the Chinese Society for Oceanography and Limnology, Member of the Chlorine Dioxide Expert Group of the Chinese Chemical Society, and Editorial Board Member of the Chinese Journal of Corrosion and Protection. Mainly engaged in research on marine atmospheric corrosion and monitoring technology, developing new electrochemical testing methods and control technologies for multiphase and multi interface complex systems such as marine atmospheric corrosion, reinforced concrete corrosion, and electrochemical engineering. Breaking through the bottleneck of ultra-thin liquid film system testing, revealing the dynamics of atmospheric corrosion; We have created a floating impedance non-destructive testing technology for steel corrosion, which has overcome the challenges in the structural health diagnosis industry. In recent years, I have led 2 National Natural Science Foundation projects, more than 10 provincial and ministerial level projects, and received 3 provincial and ministerial level science and technology awards.

 ◎Research direction

1. Marine atmospheric corrosion

2. Non-destructive testing of corrosion in reinforced concrete

3. Electrochemical engineering (metal fuel cells, inorganic salt electrocatalysis)

 ◎Educational experience

1. From September 1996 to July 2000, obtained a Bachelor's degree in Environmental Chemistry from Wuhan University

2. 2000.09-2003.07, Institute of Oceanography, Chinese Academy of Sciences, Marine Corrosion and Protection, Master

3. 2003.09-2006.07, Institute of Oceanography, Chinese Academy of Sciences, marine corrosion and protection, PhD

4. From May 2005 to November 2005, Hong Kong Baptist University, PhD in electrochemistry and joint training

 ◎Working experience

1. From July 2006 to May 2009, worked as a postdoctoral fellow in Materials Science and Engineering at Ocean University of China

2. From June 2007 to June 2008, worked as a postdoctoral fellow in Pipeline Engineering at the University of Calgary, Canada

3. From June 2009 to present, Associate Professor and Professor of Materials Science and Engineering at China University of Petroleum (East China)

4. From January 2018 to January 2019, Visiting Scholar, Electrochemical Engineering, University of Florida, USA

 ◎Fund projects

  1. From January 2023 to June 2027, * * * Marine Corrosion under Hydrostatic Pressure, Key Project, 600000 RMB, Hosted, Under Research

  2. From January 2020 to December 2023, Dynamics and Coupling Mechanism of Local Electrode Processes at the Interface between Dynamic Droplets and Pure Iron (Project No. 51971246), National Natural Science Foundation of China General Project, 720000 RMB, Hosted and Completed

  3. From December 2020 to December 2022, Visual Detection Technology for Corrosion Failure of Anti corrosion Coatings on Ships and Marine Engineering (Project No. ZX20220227), Qingdao West Coast New Area Source Innovation Technology Special Project, 200000 RMB, Hosted and Completed

  4. From October 2016 to December 2018, the technology and equipment for deep desulfurization and denitrification of flue gas with chlorine dioxide from coal-fired boilers (project number: 2016GSF117031), a key research and development plan project in Shandong Province, 150000 RMB, Hosted and Completed

  5. From May 2015 to December 2019, research and development of sulfur recovery equipment for natural gas liquefaction systems (Ministry of Industry and Information Technology Lianzhuang [2014] No. 499), Ministry of Industry and Information Technology Marine Engineering Equipment Research Project, 14.5 million yuan, technical leader, Completed

  6. From June 2007 to December 2010, the source of micro droplets and their correlation with marine atmospheric corrosion (project number 40706031) was funded by the National Natural Science Foundation of China Youth Program, with a budget of 180000 yuan. Hosted and Completed

 ◎Enterprise projects

  1. From January 2023 to December 2025, Development of a complete set of corrosion defect monitoring and testing technology, under the leadership of Endi Testing Technology (Qingdao) Co., Ltd., with a budget of 860000 yuan, currently under research

  2. From January 2023 to December 2024, the essential safety research and development project for corrosion prevention at the dock of Shihua Company, Shandong Port Group, with a budget of 340000 yuan, led by and under research

  3. From July 2022 to December 2023, Research on Optimization and Improvement of High Activity Aluminum Alloy Sacrificial Anode Materials, Shengli Oilfield Technical Testing Center, 410000 yuan, Hosted, Completed

  4. From January 2020 to July 2023, Research on Anticorrosion Technology for Oil Casings in Block 25 of Lingshui, CNOOC Hainan Branch, 800000 RMB, Hosted, Completed

 ◎Education reform projects

2021.01-2023.01, Construction of Teaching Case Library for Material Corrosion Electrochemical Testing Technology (SDYAL20035), Shandong Province Teaching Project, Hosted and Completed.

 ◎Courses

1. Undergraduate courses:

Modern Materials Science (all in English)

Principles and Technologies of Electrochemical Protection

Non destructive Testing Technology

2. Graduate courses:

Electrochemical Testing Technology for Material Corrosion

Research Methods for Corrosion Electrochemistry

 ◎Award situation

1. First Prize for Excellent Scientific and Technological Books in China's Petroleum and Chemical Automation Industry (2/4), 2021

2. Qingdao Science and Technology Progress Second Prize (1/5), 2022

3. China Petroleum and Chemical Industry Federation Science and Technology Progress Second Prize (1/9), 2023

 ◎Published papers

[1] Xiao Tang, Juanjuan Li, Yuan Wu et al., Electrochemical Formation Mechanism of Micro-droplets on Pure Iron, Frontiers in Chemistry, 9(2021): 610738

[2] X. Tang, C. Ran, M.E. Orazem, et al., Local electrochemical characteristics of pure iron under a saline droplet I : Effect of droplet size on electrochemical distribution, Electrochim. Acta. 354 (2020): 136633.

[3] X. Tang, C. Ran, M.E. Orazem, et al., Local electrochemical characteristics of pure iron under a saline droplet II : Local corrosion kinetics, Electrochim. Acta. 354 (2020): 136631.

[4] X. Tang, C. Ma, X. Zhou, X. Lyu, Q. Li, Y. Li, Atmospheric corrosion local electrochemical response to a dynamic saline droplet on pure iron, Electrochemistry Communications, 101(2019):28-34.

[5] J.S. Wang, X. Tang*, Y. Li, X.Q. Qiu, Observation and micro-electrochemical characterisation for micro-droplets in initial marine atmospheric corrosion, Corros. Eng. Sci. Technol. 51 (2016) 308-312.

[6] X. Tang, Y.F. Cheng, Quantitative characterization by micro-electrochemical measurements of the synergism of hydrogen, stress and dissolution on near-neutral pH stress corrosion cracking of pipelines, Corros. Sci. 53 (2011) 2927-2933.

[7] X. Tang, Y.F. Cheng, Micro-electrochemical characterization of the effect of applied stress on local anodic dissolution behavior of pipeline steel under near-neutral pH condition, Electrochim. Acta. 54 (2009) 1499-1505.

[8] X. Tang, L. Y. Xu, and Y. F. Cheng, Electrochemical corrosion behavior of X-65 steel in the simulated oil–sand slurry. II: Synergism of erosion and corrosion, Corrosion Science 50.5 (2008): 1469-1474.

[9] C. Zhong, X. Tang, Y.F. Cheng, Corrosion of steel under the defected coating studied by localized electrochemical impedance spectroscopy, Electrochim. Acta. 53 (2008) 4740-4747.

[10] J.W. Qiu, X. Tang, C. Zheng, Y. Li, Y. Huang, Copper complexation by fulvic acid affects copper toxicity to the larvae of the polychaete Hydroides elegans, Mar. Environ. Res. 64 (2007) 563-573.

[11] A. Q. Fu, X. Tang, and Y. F. Cheng, Characterization of corrosion of X70 pipeline steel in thin electrolyte layer under disbonded coating by scanning Kelvin probe, Corrosion Science, 51.1 (2009): 186-190.

[12] Xiao Tang, Yuzhi Zhang, Meng Liu, and Yan Li, Boundary element method (BEM) analysis for galvanic corrosion of hot dip galvanized steel immersed in seawater, Journal of Materials Sciences and Technology 25, 02 (2009): 194-198.

[13] X. Tang, Y.F. Cheng, Localized dissolution electrochemistry at surface irregularities of pipeline steel, Appl. Surf. Sci. 254 (2008) 5199-5205.

[14] D. Wang, X. Tang, Y. Qiu, F. Gan, G.Z. Chen, A study of the film formation kinetics on zinc in different acidic corrosion inhibitor solutions by quartz crystal microbalance, Corros. Sci. 47 (2005) 2157-2172.

 ◎Patents

(1) US Patent: TREE-ELECTRODE ARRAY LOCAL ELECTROCHEMICAL INFORMATION TEST SYSTEM AND TEST METHOD (US11333624B2)

(2) Tang Xiao, Zhang Bowen, Qiu Xingqi, Li Yan, a natural gas sulfur recovery reaction device under floating conditions, patent number: ZL201710231093.2

(3) Tang Xiao, Li Yan, Li Yadong, Ma Chaoran, an electrochemical testing system, patent number: ZL201810013803.9

(4) Tang Xiao, Li Qiang, Li Yan, a multiphase flow erosion local corrosion testing device, patent number: ZL201310116589.7

(5) Tang Xiao, Li Qiang, Li Yan, Corrosion Controller for Oil Well Production Equipment and Sucker Rods Using This Controller, Patent Number: ZL20131008699.1

(6) Tang Xiao, Li Xiaowei, Li Yan, Composite regeneration device and method of complex iron catalyst for natural gas desulfurization, patent number: ZL201410195059.0

(7) Tang Xiao, Liu Jie, Li Xiaowei, Li Yan, Natural gas sulfur recovery and catalyst regeneration device and method, patent number: ZL201410254862.7

(8) Tang Xiao, Li Yan, a method for evaluating the hydrogen permeation performance of coating materials and its dedicated dual electrolysis cell, patent number: ZL200610046426.6

(9) Tang Xiao, Ma Chaoran, Li Yan, Lv Xiaolei, Three electrode array local electrochemical information testing system and testing method, patent number: ZL201710319384.7