工作经历：

2022.10-至今 中国科学院金属研究所 项目研究员

2021.05-至今 中国科学院金属研究所 研究部主任助理

2019.10-2022.09 中国科学院金属研究所 副研究员

2019.10-2020.04 University of Alberta 博士后

2017.07-2019.09 中国科学院金属研究所 助理研究员

教育经历：

2012.09-2017.06 中国科学院大学 腐蚀科学与防护 博士

2008.09-2012.06 北京理工大学 材料科学与工程 学士

1. 冲刷腐蚀机理、预测及防护技术研究

2. 耐磨耐蚀合金研发与应用

3. 垢下腐蚀机理及特种缓蚀剂研发与应用

1.中国腐蚀与防护学会理事、磨蚀与防护技术专业委员会常务委员、电化学及测试方法专业委员会委员、缓蚀剂与水处理专业委员会委员、青年工作委员会委员

2.《Corrosion Communications》期刊学科编辑及青年编委

3.《中国腐蚀与防护学报》期刊青年编委

1.2022年入选中国第七届中国科协青年人才托举工程

2.2022年获中国科学院沈阳分院2021-2022年度优秀共产党员

3.2022年获全国腐蚀电化学及测试方法学术年会优秀论文奖

4.2021年获中国科学院金属研究所首届（2021）青年学者论坛一等奖

5.2021年获金属学报（英文版）ESI高被引论文奖

近期发表论文 

[1] J. Yang, Z.B. Wang*, Y.X. Qiao, Y.G. Zheng*, Synergistic effects of deposits and sulfate reducing bacteria on the corrosion of carbon steel, Corrosion Science 199 (2022) 110210.

[2] J. Jiang, Z.B. Wang*, S.J. Pang, Y.G. Zheng, Y. Li*, Oxygen impurity improving corrosion resistance of a Zr-based bulk metallic glass in 3.5 wt% NaCl solution, Corrosion Science 192 (2021) 109867.

[3] L. Pang, Z.B. Wang*, M.H. Lu, Y. Lu, X. Liu, Y.G. Zheng*, Inhibition performance of benzimidazole derivatives with different heteroatoms on the under-deposit corrosion of carbon steel in CO2-saturated solution, Corrosion Science 192 (2021) 109841.

[4] Z.B. Wang, C. Sun, L.L. Li, M. Roostaei, V. Fattahpour, M. Mahmoudi, H.B. Zeng, Y.G. Zheng*, J.L. Luo*, A new method to obtain the repassivation time of passive materials based on the single particle impingement, Corrosion Science 170 (2020) 108717.

[5] L.L. Li, Z.B. Wang*, Y.G. Zheng, Interaction between pitting corrosion and critical flow velocity for erosion-corrosion of 304 stainless steel under jet slurry impingement, Corrosion Science 158 (2019) 108084.

[6] Z.B. Wang, H.X. Hu, Y.G. Zheng*, Synergistic effects of fluoride and chloride on general corrosion behavior of AISI 316 stainless steel and pure titanium in H2SO4 solutions, Corrosion Science 130 (2018) 203-217.

[7] Z.B. Wang, H.X. Hu, Y.G. Zheng*, W. Ke, Y.X. Qiao*, Comparison of the corrosion behavior of pure titanium and its alloys in fluoride-containing sulfuric acid, Corrosion Science 103 (2016) 50-65.

[8] Z.B. Wang, H.X. Hu, Y.G. Zheng*, Determination and explanation of the pH-related critical fluoride concentration of pure titanium in acidic solutions using electrochemical methods, Electrochimica Acta 170 (2015) 300-310.

[9] Z.B. Wang, H.X. Hu, C.B. Liu, Y.G. Zheng*, The effect of fluoride ions on the corrosion behavior of pure titanium in 0.05 M sulfuric acid, Electrochimica Acta 135 (2014) 526-535.

[10] L.L. Li, Z.B. Wang*, S.Y. He, Y.G. Zheng, Correlation between depassivation and repassivation processes determined by single particle impingement: Its crucial role in the phenomenon of critical flow velocity for erosion-corrosion, Journal of Materials Science & Technology 89 (2021) 158-166.

[11] L. Pang, Z.B. Wang*, Y.G. Zheng, X.M. Lai, X. Han, On the localised corrosion of carbon steel induced by the in-situ local damage of porous corrosion products, Journal of Materials Science & Technology 54 (2020) 95-104.

[12] Z.B. Wang, Y.G. Zheng*, J.Z. Yi, The role of surface film on the critical flow velocity for erosion-corrosion of pure titanium, Tribology International 133 (2019) 67-72.

[13] J. Jiang, Z.B. Wang*, Y.G. Zheng, Y. Li*, Effect of oxygen impurity on corrosion behavior of a Zr-based bulk metallic glass in 0.5 M H2SO4 and 0.5 M NaOH solutions, Materials Letters 330 (2023) 133231.

[14] Z.J. Shi, Z.B. Wang*, X.D. Wang, S. Zhang*, Y.G. Zheng, Effect of thermally induced B2 phase on the corrosion behavior of an Al0.3CoCrFeNi high entropy alloy, Journal of Alloys and Compounds 903 (2022) 163886.

[15] Z.B. Wang, L. Pang, Y.G. Zheng*, A review on under-deposit corrosion of pipelines in oil and gas fields: Testing methods, corrosion mechanisms and mitigation strategies, Corrosion Communications 7 (2022) 70-81.

[16] Z.B. Wang, Y.G. Zheng*, Critical flow velocity phenomenon in erosion-corrosion of pipelines: determin

学术活动（近期国际国内会议报告及任职等）

[1] 王政彬，李琳琳，郑玉贵，再钝化性能在钝性材料冲刷腐蚀临界流速现象中的关键作用，第十一届全国腐蚀与防护大会，分会特邀报告，沈阳，2021.7.2-4