周炎（副教授）

»姓名：周炎

»系属：新能源材料系

»学位：博士

»职称：副教授

»专业：电化学

»导师类别：硕导

»电子邮箱：yanzhou@upc.edu.cn

»联系电话：18953243586

»通讯地址：山东省青岛市黄岛区长江西路66号

»概况

山东淄博人，九三学社社员，淄博市第一批氢能及燃料电池产业专家智库成员。本科、博士毕业于英国赫尔大学，后在赫尔大学继续从事科研工作数月。2013年8月入职中国石油大学（华东）从事电化学及新能源材料方面的研究。研究方向涵盖例如纳米材料的合成及其电催化性质的研究，无机纳米材料制备无酶传感器，燃料电池等方面。英国皇家化学会会员，中国化学会会员。

 ◎研究方向

(1)氢能：电解水制氢、氢氧燃料电池、氨氢燃料电池关键催化材料

(2)传感：电化学无酶传感器（葡萄糖、胆固醇）

(3)电化学机理研究

 ◎教育经历

(1)2009.9–2013.1, 赫尔大学（英国）, 化学, 博士

(2)2006.9–2009.7, 赫尔大学（英国）, 化学及分析化学和毒理学, 学士

 ◎工作经历

(1) 2020.01-至今中国石油大学（华东），材料科学与工程学院，新能源材料系，副教授

(2) 2018.07-2010.12 中国石油大学（华东），材料科学与工程学院，新能源材料系，讲师

(3) 2013.8-2018.06, 中国石油大学（华东）, 理学院化学系，讲师

(4) 2013.1-2013.3, 赫尔大学, 化学系, 合同研究员

 ◎学术兼职

英国皇家化学会会员、中国化学会会员

 ◎主讲课程

《专业外语》、《电化学基础》、《新生研讨课》等

 ◎指导研究生及博士后

2023级

硕士：胥嘉欣、隋德昇、陈渝鑫

博士：张慧

2022级

硕士：张文慧、崔倩

2021级

硕士：唐含、张未、刘昕

博士：罗佳冰（协助指导）

2020级

硕士：孟云龙、庞鑫、顾雨峰、杨青怡

2019级

硕士：尤紫晗、夏菡菡、孙凤超

博士：王兴兆（协助指导）

2018级

硕士：郭千瑜、罗佳冰

2017级

硕士：于鑫萍

博士：王雪媛（协助指导）

2016级

硕士：张景彤

2014级

硕士：肖华清

 ◎承担项目

（1）山东省自然科学基金面上项目，ZR2023MB078，基于界面电荷调控策略的MO@RuO₂核壳结构可控合成及电催化析氧研究，2024/01-2026/12，在研，主持

（2）横向项目，富氢水机用PEM电解槽开发技术服务，2022/07-2024/08，在研，主持

（3）国家自然科学基金青年基金项目，21805308，高效二维三元TMC自支撑催化电极材料的精确合成与控制，2019/01-2021/12，已结题，主持

（4）山东省重点研发计划，2019GSF109075，电化学催化固氮关键技术的研究与应用，2019/07-2021/07，已结题，主持

（5）山东省自然科学基金青年基金项目，ZR2017QB015，碳基底诱导二维过渡金属硫族化合物的取向生长及电催化性能研究，2017/08-2019/12，已结题，主持

（6）自主创新科研计划项目，27R1908011A，高效二维双金属化合物材料的结构调控及电化学性能研究（材料学科发展专项子课题12），2019/01-2021/12，已结题，主持

（7）横向项目，HX20200706，光电联合制氢装置基础研究，2020/10-2022/09，在研，主持

（8）自主创新科研计划项目，14CX02154A，二茂铁多肽水凝胶的合成及其在生物燃料电池中的应用，2014/01-2015/12，已结题，主持

（9）校人才引进项目，2013053，基于多肽分子修饰的电化学生物酶传感器，2014/01-2015/12，主持

 ◎论文

2024年

[1] W. Zhang, J. Luo, H. Tang, S. Wang, W. Li, J. Zhang, Y. Zhou*, Co-doped RuO2 nanoparticles with enhanced catalytic activity and stability for the oxygen evolution reaction, Dalton Transactions, 53 (2024) 1031-1039.

[2] J. Luo, X. Wang, S. Wang, W. Li, Y. Li, T. Wang, F. Xu, Y. Liu, Y. Zhou*, J. Zhang*, MOF-derived S-doped NiCo2O4 hollow cubic nanocage for highly efficient electrocatalytic oxygen evolution, Journal of Colloid and Interface Science, 656 (2024) 297-308.

[3] X. Liu, J. Luo, X. Liu, S. Wang, W. Li, J. Zhang*, Y. Zhou*, Nitrogen-Doped Carbon Nanosheets Supported Co for Efficient and Stable Electrocatalytic Oxygen Reduction, ACS Applied Nano Materials, 7 (2024) 4491-4500.

2023年

[1] Y. Zhou*, Y. Meng, X. Wang, J. Luo, H. Xia, W. Li, J. Zhang, Enhancing electro-reduction of nitrite to ammonia by loading Co₃O₄ on CuO to construct elecrocatalytic dual-sites, Dalton Trans, 52 (2023) 3260-3264.

[2] Y. Zhou*, Q. Guo, J. Luo, X. Wang, F. Sun, C. Wang, S. Wang, J. Zhang, The influence of increased content of Ni(III) in NiFe LDH via Zn doping on electrochemical catalytic oxygen evolution reaction, International Journal of Hydrogen Energy, 48 (2023) 4984-4993.

[3] J. Zhang, X. Pang, J. Luo, X. Wang, S. Wang, Y. Zhou*, Ru-doped CoS1.097 nanoparticles for improved electrocatalytic hydrogen evolution reaction, New Journal of Chemistry, 47 (2023) 5169-5173.

[4] C. Yue, N. Liu, Y. Li, Y. Liu, F. Sun, W. Bao, Y. Tuo*, Y. Pan, P. Jiang, Y. Zhou*, Y. Lu*, From atomic bonding to heterointerfaces: Co₂P/WC constructed by lacunary polyoxometalates induced strategy as efficient hydrogen evolution electrocatalysts at all pH values, Journal of Colloid and Interface Science, 645 (2023) 276-286.

[5] X. Wang, J. Luo, Y. Tuo, Y. Gu, W. Liu, S. Wang, Y. Zhou*, J. Zhang*, Hierarchical heterostructure of NiFe₂O₄ nanoflakes grown on the tip of NiCo₂O₄ nanoneedles with enhanced interfacial polarization effect to achieve highly efficient electrocatalytic oxygen evolution, Chemical Engineering Journal, 457 (2023) 141169.

[6] Y. Tuo, W. Liu, Q. Lu, X. Wang, J. Luo, S. Wang, Y. Zhou*, M. Wang, X. Sun, X. Feng, M. Wu, D. Chen, J. Zhang*, SO₄²⁻ mediated CO₂ activation on metal electrode for efficient CO₂ electroreduction, Chemical Engineering Journal, 464 (2023) 142510.

[7] J. Luo, Y. Zhou*, X. Wang, Y. Gu, W. Liu, S. Wang, J. Zhang*, CoMoO₄-CoP/NC heterostructure anchored on hollow polyhedral N-doped carbon skeleton for efficient water splitting, Journal of Colloid and Interface Science, 648 (2023) 90-101.

[8] J. Luo, X. Wang, J. Zhang, Y. Zhou*, Fe-doped Co₃O₄ anchored on hollow carbon nanocages for efficient electrocatalytic oxygen evolution, 燃料化学学报, 51 (2023).

[9] J. Luo, X. Wang, Y. Gu, S. Wang, Y. Li, T. Wang, Y. Liu, Y. Zhou*, J. Zhang*, Hierarchical sheet-like W-doped NiCo₂O₄ spinel synthesized by high-valence oxyanion exchange strategy for highly efficient electrocatalytic oxygen evolution reaction, Chemical Engineering Journal, 472 (2023) 144839.

2022年

[10] Q. Yang, F. Sun, X. Wang, J. Luo, S. Wang*, C. Jia, Y. Pan*, J. Zhang, Y. Zhou*, Surface charge modulation enhanced high stability of gold oxidation intermediates for electrochemical glucose sensors, Analytical Methods, 14 (2022) 4474-4484.

[11] X. Wang, Y. Zhou*, J. Luo, F. Sun, J. Zhang*, Synthesis of V-doped urchin-like NiCo₂O₄ with rich oxygen vacancies for electrocatalytic oxygen evolution reactions, Electrochimica Acta, 406 (2022) 139800.

[12] X. Wang, J. Luo, Y. Zhou*, J. Zhang*, Hierarchical heterostructure consists of Al³⁺ doped NiFe₂O₄ nanocubes on NiCo₂O₄ nanosheets for efficient electrocatalytic water splitting, Journal of Physics Conference Series, 2334 (2022) 012008.

[13] F. Sun, X. Wang, Z. You, H. Xia, S. Wang, C. Jia, Y. Zhou*, J. Zhang, Sandwich structure confined gold as highly sensitive and stable electrochemical non-enzymatic glucose sensor with low oxidation potential, Journal of Materials Science & Technology, 123 (2022) 113-122.

[14] J. Luo^#, Y. Zhou^#, Y. Tuo, Y. Gu, X. Wang, Q. Guo, C. Chen, D. Wang, S. Wang, J. Zhang, Interfacial polarization in ultra-small Co₃S₄−MoS₂ heterostructure for efficient electrocatalytic hydrogen evolution reaction, Applied Materials Today, 26 (2022) 101311.

[15] J. Luo, X. Wang, Y. Gu, D. Wang, S. Wang, W. Li, Y. Zhou*, J. Zhang*, Constructing hollow nanocages of Co₃O₄-CoMoO₄ heterostructure for efficient electrocatalytic oxygen evolution reaction, Applied Surface Science, 606 (2022).

2021年

[16] H. Yang, Y. Zhou*, K. Chen, X. Yu, F. Sun, M. Wang, Z. Cheng, J. Zhang*, Q.J. Niu*, Effects of PbO₂/Pb₃O₄ ratio alteration for enhanced electrochemical advanced oxidation performance, Journal of Solid State Chemistry, 301 (2021) 122277.

[17] X. Wang, Y. Tuo, Y. Zhou*, D. Wang, S. Wang, J. Zhang*, Ta-doping triggered electronic structural engineering and strain effect in NiFe LDH for enhanced water oxidation, Chemical Engineering Journal, 403 (2021) 126297.

[18] F. Sun, Y. Zhou*, Z. You, H. Xia, Y. Tuo, S. Wang, C. Jia, J. Zhang*, Bi-Functional Fe₃O₄ /Au/CoFe-LDH Sandwich-Structured Electrocatalyst for Asymmetrical Electrolyzer with Low Operation Voltage, Small, 17 (2021) e2103307.

[19] C. Chen, Z. Yang, W. Liang, H. Yan, Y. Tuo, Y. Li, Y. Zhou*, J. Zhang*, Ultra-small Co/CoO nanoparticles dispersed on N-doped carbon nanosheets for highly efficient electrocatalytic oxygen evolution reaction, Journal of Energy Chemistry, 55 (2021) 345-354.

2020年

[20] Y. Zhou*, J. Zhang, F. Sun, X. Yu, W. Kang, J. Zhang, One-step synthesis of Co₉S₈@Ni₃S₂ heterostructure for enhanced electrochemical performance as sodium ion battery anode material and hydrogen evolution electrocatalyst, Journal of Solid State Chemistry, 285 (2020) 121230.

[21] Y. Zhou, J. Zhang, H. Ren, Y. Pan, Y. Yan, F. Sun, X. Wang, S. Wang, J. Zhang*, Mo doping induced metallic CoSe for enhanced electrocatalytic hydrogen evolution, Applied Catalysis B: Environmental, 268 (2020) 118467.

[22] Y. Zhou*, X. Yu, F. Sun, J. Zhang, MoP supported on reduced graphene oxide for high performance electrochemical nitrogen reduction, Dalton Trans, 49 (2020) 988-992.

[23] H. Yang, Y. Bi, M. Wang, C. Chen, Z. Xu, K. Chen, Y. Zhou*, J. Zhang*, Q.J. Niu*, beta-FeOOH self-supporting electrode for efficient electrochemical anodic oxidation process, Chemosphere, 261 (2020) 127674.

[24] Y. Tuo, X. Wang, C. Chen, X. Feng, Z. Liu, Y. Zhou*, J. Zhang*, Identifying the role of Ni and Fe in Ni–Fe co-doped orthorhombic CoSe₂ for driving enhanced electrocatalytic activity for oxygen evolution reaction, Electrochimica Acta, 335 (2020) 135682.

[25] Y. Lu*, X. Guo, L. Yang, W. Yang, W. Sun, Y. Tuo*, Y. Zhou*, S. Wang, Y. Pan, W. Yan, D. Sun, Y. Liu, Highly efficient CoMoS heterostructure derived from vertically anchored Co₅Mo₁₀ polyoxometalate for electrocatalytic overall water splitting, Chemical Engineering Journal, 394 (2020) 124849.

2019年

[26] Y. Zhou*, X. Yu, X. Wang, C. Chen, S. Wang, J. Zhang, MoS₂ nanosheets supported gold nanoparticles for electrochemical nitrogen fixation at various pH value, Electrochimica Acta, 317 (2019) 34-41.

[27] X. Wang, Y. Zhou*, Y. Tuo, Y. Lin, Y. Yan, C. Chen, Y. Li, J. Zhang*, Synthesis and identifying the active site of Cu₂Se@CoSe nano-composite for enhanced electrocatalytic oxygen evolution, Electrochimica Acta, 320 (2019) 134589.

[28] X. Wang, Y. Zhou*, M. Liu, C. Chen, J. Zhang*, Colloidal synthesis of high-performance FeSe/CoSe nanocomposites for electrochemical oxygen evolution reaction, Electrochimica Acta, 297 (2019) 197-205.

[29] F. Sun, S. Wang, Y. Wang, J. Zhang, X. Yu, Y. Zhou*, J. Zhang, Synthesis of Ni-Co Hydroxide Nanosheets Constructed Hollow Cubes for Electrochemical Glucose Determination, Sensors, 19 (2019) 31277330.

2019年以前

[30] J. Zhang, F. Zhao, K. Du, Y. Zhou*, Self-Supported NiSe/Ni Foam: An Efficient 3D Electrode for High-Performance Supercapacitors, Nano, 13 (2018) 1850136.

[31] J. Zhang, Y. Chen, M. Liu, K. Du, Y. Zhou*, Y. Li, Z. Wang, J. Zhang*, 1T@2H-MoSe₂ nanosheets directly arrayed on Ti plate: An efficient electrocatalytic electrode for hydrogen evolution reaction, Nano Research, 11 (2018) 4587-4598.

[32] F.-c. Sun, J.-t. Zhang, H. Ren, S.-t. Wang, Y. Zhou*, J. Zhang, “Dry” NiCo2O4 nanorods for electrochemical non-enzymatic glucose sensing, Chinese Journal of Chemical Physics, 31 (2018) 799-805.

[33] Y. Zhou*, H. Xiao, S. Zhang, Y. Li, S. Wang, Z. Wang, C. An, J. Zhang*, Interlayer expanded lamellar CoSe₂ on carbon paper as highly efficient and stable overall water splitting electrodes, Electrochimica Acta, 241 (2017) 106-115.

[35] Y. Zhou, J. Li, S. Wang, J. Zhang, Z. Kang*, From MOF membrane to 3D electrode: a new approach toward an electrochemical non-enzymatic glucose biosensor, Journal of Materials Science, 52 (2017) 12089-12097.

[36] S. Zhang, C. Li, H. Xiao, G. Wei, Y. Zhou*, Z. Wang, J. Zhang, C. An*, Synthesis of 3D flower-like cobalt sulfide hierachitecture for high-performance electrochemical energy storage, Journal of Nanoparticle Research, 19 (2017) 202.

[37] H. Xiao, S. Wang, S. Zhang, Y. Wang, Q. Xu, W. Hu, Y. Zhou*, Z. Wang, C. An, J. Zhang*, Interlayer expanded molybdenum disulfide nanosheets assembly for electrochemical supercapacitor with enhanced performance, Materials Chemistry and Physics, 192 (2017) 100-107.

2016年

[38] Y. Zhou, H. Xiao, S. Wang, X. Pan, Z. Wang, C. An*, J. Zhang*, Synthesis of layer-expanded MoS₂ nanosheets/carbon fibers nanocomposites for electrochemical hydrogen evolution reaction, Materials Chemistry and Physics, 183 (2016) 18-23.

[39] H. Xiao, S. Wang*, C. Wang, Y. Li, H. Zhang, Z. Wang, Y. Zhou*, C. An, J. Zhang, Lamellar structured CoSe₂ nanosheets directly arrayed on Ti plate as an efficient electrochemical catalyst for hydrogen evolution, Electrochimica Acta, 217 (2016) 156-162.

[40] S. Wang, C. Wang, G. Wei, H. Xiao, N. An, Y. Zhou*, C. An, J. Zhang, Non-enzymatic glucose sensor based on facial hydrothermal synthesized NiO nanosheets loaded on glassy carbon electrode, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 509 (2016) 252-258.

2010

[41] Y. Zhou, A. Andreou, E. Biktagirov, J. Eames, J. Wadhawan*, Comparison of Birch with electrochemical reduction of 2,3-diphenyl-1,4-diazaspiro[4.5]deca-1,3-diene, Electrochemistry Communications, 12 (2010) 1493-1497.

 ◎专利

（1）一种二硒化铁纳米复合材料及其合成方法与应用，周炎等，2019

（2）一种用于电催化合成氨的Bi-MoS2纳米复合材料的制备方法，周炎等，2022

（3）一种高性能镍铁基析氧电催化纳米复合材料及其制备方法与应用，周炎等，2023

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