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个人信息Personal Information
教授 博士生导师 硕士生导师
主要任职:无
其他任职:无
性别:男
毕业院校:西安交通大学&美国犹他大学联合培养
学历:博士研究生毕业
学位:工学博士学位
在职信息:在职
所在单位:环境科学与工程学院
入职时间:2019-06-14
学科:环境科学与工程
环境工程
办公地点:山东大学(青岛校区)会文南楼A座
涉及环境、化学、能源、材料、电子等多个学科,近几年主要从事以下研究:
(一)裂解水产氢技术(重点开展基于海水的绿氢制备技术研发,涵盖光催化、PEM电催化及光热催化等产氢路径):
1. He, Z.; Kim, C.; Lin, L.H.; Jeon, T.H.; Lin, S.; Wang, X.C.; Choi, W. Formation of heterostructures via direct growth CN on h-BN porous nanosheets for metal-free photocatalysis. Nano Energy 2017, 42, 58-68.
2. He, Z.; Kim, C.; Jeon, T.H.; Choi, W. Hydrogenated heterojunction of boron nitride and titania enables the photocatalytic generation of H2 in the absence of noble metal catalysts. Applied Catalysis B: Environmental 2018, 237, 772-782.
3. Xiao, L.H.; Li, X.; Zhang, J.; He, Z.L. MgB4 MXene-like nanosheets for photocatalytic hydrogen evolution. ACS Applied Nano Materials 2021, 4, 12779-12787.
4. Li, X.; Zhang, J.; Zhang, S.J.; Xu, S.S.; Wu, X.G.; Chang, J.C.; He, Z.L. Hexagonal boron nitride composite photocatalysts for hydrogen production. Journal of Alloys and Compounds 2021, 864, 158153.
5. Dai, M.; He, Z.; Zhang, P.; Li, X.; Wang, S. ZnWO4-ZnIn2S4 S-scheme heterojunction for enhanced photocatalytic H2 evolution. Journal of Materials Science & Technology 2022, 122, 231-242.6. Cao, W.R.; He, Z.L.; Dai, M.; Wang, G.Z.; Huang, G.H.; Wang, S.G. Electronic structure modulation of bimetallic sulfides for efficient sacrificial-agent-free photocatalytic H2 evolution. ACS Applied Energy Materials 2023, 6, 4715-4723.
7. Dai, M.; He, Z.; Cao, W.; Zhang, J.; Chen, W.; Jin, Q.; Que, W.; Wang, S. Rational construction of S-scheme BN/MXene/ZnIn2S4 heterojunction with interface engineering for efficient photocatalytic hydrogen production and chlorophenols degradation. Separation and Purification Technology 2023, 309, 123004.
(二)光催化高级氧化水处理技术(主要包括光催化处理抗生素废水、有机工业废水与含重金属废水):
1. He, Z.; Zhang, J.; Li, X.; Guan, S.; Dai, M.; Wang, S. 1D/2D heterostructured photocatalysts: From design and unique properties to their environmental applications. Small 2020, 16, 2005051.
2. Zhang, S.J.; He, Z.L.; Xu, S.S.; Li, X.; Zhang, J.; Zhan, X.P.; Dai, M.; Wang, S.G. In situ liquid-phase growth strategies of g-C3N4 solar-driven heterogeneous catalysts for environmental applications. Solar RRL 2021, 5, 2100233.
3. Yu, H.; Xu, S.; Zhang, S.; Wang, S.; He, Z. In-situ construction of core–shell structured TiB2-TiO2@g-C3N4 for efficient photocatalytic degradation. Applied Surface Science 2022, 579, 152201.
4. Dai, M.; Yu, H.; Chen, W.; Qu, K.-A.; Zhai, D.; Liu, C.; Zhao, S.; Wang, S.; He, Z. Boosting photocatalytic activity of CdLa2S4/ZnIn2S4 S-scheme heterojunctions with spatial separation of photoexcited carries. Chemical Engineering Journal 2023, 470, 144240.
5. Jin, Q.; Zheng, Z.; Feng, Y.; Tian, S.; He, Z. Multi-Walled Carbon Nanotubes Modified NiCo2S4 for the Efficient Photocatalytic Reduction of Hexavalent Chromium. C-Journal of Carbon 2023, 9, 99.
6. Chen, W.; Dai, M.; Xiang, L.; Zhao, S.; Wang, S.; He, Z. Assembling S-scheme heterojunction between basic bismuth nitrate and bismuth tungstate with promoting charges' separation for accelerated photocatalytic sulfamethazine degradation. Journal of Materials Science & Technology 2024, 171, 185-197.
7. Feng, Y.X.; Yu, H.J.; Lu, T.G.; Zheng, Z.Y.; Tian, S.; Xiang, L.; Zhao, S.; Wang, S.G.; He, Z.L. Synergistic Cu single-atoms and clusters on tubular carbon nitride for efficient photocatalytic performances. Rare Metals 2024, 43, 5891-5904.
(三)异质结催化剂设计(构筑具有特殊晶体结构、能带结构、微观形貌的异质结催化剂,关注组份间相互作用、电荷传输与分离、催化反应机制等):
1. He, Z.; Zhang, J.; Li, X.; Guan, S.; Dai, M.; Wang, S. 1D/2D heterostructured photocatalysts: From design and unique properties to their environmental applications. Small 2020, 16, 2005051.
2. Zhang, J.; Dai, M.; Zhang, S.; Dai, M.; Zhang, P.; Wang, S.; He, Z. Recent Progress on Carbon‐Nanotube‐Based Materials for Photocatalytic Applications: A Review. Solar RRL 2022, 6, 2200243.
3. Dai, M.; He, Z.; Cao, W.; Zhang, J.; Chen, W.; Jin, Q.; Que, W.; Wang, S. Rational construction of S-scheme BN/MXene/ZnIn2S4 heterojunction with interface engineering for efficient photocatalytic hydrogen production and chlorophenols degradation. Separation and Purification Technology 2023, 309, 123004.
4. Dai, M.; Yu, H.; Chen, W.; Qu, K.-A.; Zhai, D.; Liu, C.; Zhao, S.; Wang, S.; He, Z. Boosting photocatalytic activity of CdLa2S4/ZnIn2S4 S-scheme heterojunctions with spatial separation of photoexcited carries. Chemical Engineering Journal 2023, 470, 144240.
5. Yu, H.; Dai, M.; Zhang, J.; Chen, W.; Jin, Q.; Wang, S.; He, Z. Interface engineering in 2D/2D heterogeneous photocatalysts. Small 2023, 19, 2205767.
6. Qin, S.; Xu, R.; Jin, Q.; Wang, S.; Ren, Y.; Huang, Y.; Zheng, Z.; Xiao, L.; Zhai, D.; Wang, S.; et al. Efficient Photocatalytic Reduction of Hexavalent Chromium by NiCo2S4/BiOBr Heterogeneous Photocatalysts. Coatings 2024, 14, 1492.
7. Ren, Y.; Huang, Y.L.; Zheng, Z.Y.; Dai, M.; Li, H.S.; Chang, J.C.; Lu, T.G.; Gu, K.; Wang, S.G.; He, Z.L. Construct a heterojunction interface to induce and complete hole-dominated cascade reaction, Small, 2025, e08444
(四)复合纤维织物器件(包括但不限于应变传感器、湿度传感器、光催化织物、锂电池、超级电容器等各类功能器件):
1. He, Z.; Byun, J.-H.; Zhou, G.; Park, B.-J.; Kim, T.-H.; Lee, S.-B.; Yi, J.-W.; Um, M.-K.; Chou, T.-W. Effect of MWCNT content on the mechanical and strain-sensing performance of Thermoplastic Polyurethane composite fibers. Carbon 2019, 146, 701-708.
2. He, Z.; Zhou, G.; Byun, J.H.; Lee, S.K.; Um, M.K.; Park, B.; Kim, T.; Lee, S.B.; Chou, T.W. Highly stretchable multi-walled carbon nanotube/thermoplastic polyurethane composite fibers for ultrasensitive, wearable strain sensors. Nanoscale 2019, 11, 5884-5890.
3. Zhang, S.; He, Z.; Zhou, G.; Jung, B.-M.; Kim, T.-H.; Park, B.-J.; Byun, J.-H.; Chou, T.-W. High conductive free-written thermoplastic polyurethane composite fibers utilized as weight-strain sensors. Composites Science and Technology 2020, 189, 108011.
4. Qu, K.-A.; Chen, W.; Guo, J.; He, Z. A mini-review on preparation of functional composite fibers and their based devices. Coatings 2022, 12, 473.
5. Zhang, J.; Li, X.; Guo, J.; Zhou, G.H.; Xiang, L.; Wang, S.G.; He, Z.L. Novel TiO2/TPU composite fiber-based smart textiles for photocatalytic applications. Materials Advances 2022, 3, 1518–1526.
6. He, Z.; Zhou, G.; Oh, Y.; Jung, B.M.; Um, M.K.; Lee, S.K.; Song, J.I.; Byun, J.H.; Chou, T.W. Ultrafast, highly sensitive, flexible textile-based humidity sensors made of nanocomposite filaments. Materials Today Nano 2022, 18, 100214.
7. Xiao, L.; Zhang, J.; Lu, T.; Zhou, G.; Ren, Y.; Zheng, Z.; Yuan, X.; Wang, S.; He, Z. High-strength TiO2/TPU composite fiber based textiles for organic pollutant removal. NPJ Clean Water 2024, 7, 98.
(五)光催化耦合水处理技术(面向复杂工况污水处理需求,研发光催化-吸附、光催化-膜、光催化-芬顿、光催化-PMS等耦合技术;并运用3D打印技术构建高效定制化反应器,优化系统传质性能):
1. Tian, S.; Feng, Y.; Zheng, Z.; He, Z. TiO2-Based Photocatalytic Coatings on Glass Substrates for Environmental Applications. Coatings 2023, 13, 1472.
2. Zheng, Z.Y.; Tian, S.; Feng, Y.X.; Zhao, S.; Li, X.; Wang, S.G.; He, Z.L. Recent advances of photocatalytic coupling technologies for wastewater treatment. Chinese Journal of Catalysis 2023, 54, 88-136.
3. Feng, Y.-X.; Yu, H.-J.; Lu, T.-G.; Zheng, Z.-Y.; Tian, S.; Xiang, L.; Zhao, S.; Wang, S.-G.; He, Z.-L. Synergistic Cu single-atoms and clusters on tubular carbon nitride for efficient photocatalytic performances. Rare Metals 2024, 43, 5891-5904.
4. Xiao, L.; Zhang, S.; Cui, H.; Chang, J.; Feng, Y.; Wang, S.; He, Z. Promoted photocatalytic performances over Ti3+-B co-doped TiO2/BN with high carrier transfer and absorption capabilities driven by SWCNT addition. Materials Science in Semiconductor Processing 2024, 177, 108364.
5. Qu, K.; Li, H.; Sun, J.; Wang, S.; He, Z.; Wang, S.G. Rationally designed assembled FeV3O8/g-C3N4 heterojunction improve carrier transport separation and efficiently promote the degradation of 2,4,6-TCP by photo-activated peroxymonosulfate. Materials Science in Semiconductor Processing 2025, 194, 109541.
6. Xu, R.; Qin, S.; Lu, T.; Wang, S.; Chen, J.; He, Z. Engineering Photocatalytic Membrane Reactors for Sustainable Energy and Environmental Applications. Catalysts 2025, 15, 947.
7. Zheng, Z.Y.; Ren, Y.; Dai, M.; Li, H.S.; Cui, H.; Wang, S.; Wang, S.G.; He, Z.L. An eco-friendly photocatalytic coupling capacitive deionization system for efficient chlorophenol wastewater treatment. Chinese Journal of Catalysis 2025, 79, 148-161.
欢迎勤奋上进的博士后、博士、硕士、本科生及高中生加入课题组,开展相关科研工作。
诚挚欢迎大家加入课题组,在未来的日子里共同进步。
博士后:
课题组常年招收博士后2-3名,欢迎具有环境、化学、材料、电子(传感器、能源器件方向)等相关背景的博士生加入课题组(具体待遇根据科研能力享受特别资助、重点资助、项目资助),特别资助类博士后期满达到培养要求可转聘相关学科教师岗位,也可参与齐鲁青年学者等人才项目的选拔。
博士生研究生:
课题组每年招收博士生1~2名(优先考虑具有相关领域研究经验、勤奋上进,服从实验室科研规划和管理的同学),博士招生名额每年12月中旬或4月下旬才能确定,报考前大家先咨询是否有名额。
硕士生研究生:
课题组每年招收硕士生1~2名(优先考虑勤奋上进、刻苦钻研、有志于在科研上有所突破的同学),诚挚欢迎大家的加入,为课题组注入新的血液。
毕业要求:
博士毕业要求:
注重创新性、系统性、完整性,至少完成4章节研究内容,发表2篇一区论文或4篇二区论文且至少2篇研究论文。
硕士毕业要求:
主要从事基础理论和应用研究,完成2个以上完整且相互关联的研究体系,发表1篇二区以上论文或2篇SCI论文且至少有1篇研究论文。
倡导大家健康地进行有组织的科研,勤奋上进谦虚严谨,积累经验提升本领。
保证有效的科研时间:
按时高效地完成科研任务;
保持良好的科研环境:
积极进取、踏实勤奋、追求卓越;
培养良好的科研素养:
坚持阅读文献资料,开拓自己的学术视野;
认真做好实验记录,养成良好的科研习惯。
主动交流,相互协作:
积极讨论,相互合作,主动融入集体。
每周与导师至少面对面讨论1次。
课题组文章推送
何作利教授团队在光催化污染物降解领域取得系列进展
https://www.view.sdu.edu.cn/info/1101/207527.htm
https://www.huanke.sdu.edu.cn/info/1029/6887.htm
山东大学何作利教授团队Small:构建异质结界面来诱发和完成空穴主导的级联反应
https://mp.weixin.qq.com/s/LEj6l6AWEZCgO24Je_WmwQ
山东大学何作利教授团队Chinese J. Catal.:用于高效氯酚废水处理的环保型“光催化-电容去离子”耦合系统
https://mp.weixin.qq.com/s/E83KrU_gAeqxT5aHc53KLA
https://mp.weixin.qq.com/s/fUYnn4uwqbXKMhv_wNm-6w
山东大学何作利教授团队《催化学报》:光催化耦合电容去离子,打造氯酚废水绿色处理新范式
https://mp.weixin.qq.com/s/LlSUH27klEnGyOzjaKhuKg
山东大学NPJ Clean Water:用于有机污染物去除的高强度TiO2/TPU光催化复合纤维织物
https://mp.weixin.qq.com/s/7tRZnR-UtKXDaXUqCX4ytw
https://mp.weixin.qq.com/s/PQ-YYUeqwF3qbJj9StxJyw
https://mp.weixin.qq.com/s/ol224Lw2MzqSWiGtcervXA
Rare Metals 山东大学何作利:管状氮化碳上协同Cu单原子和团簇以实现高效的光催化性能
https://mp.weixin.qq.com/s/5cGL4QhYQdCtYoLbbiE5jA
山东大学何作利课题组JMST:碱式硝酸铋/钨酸铋S型异质结促进电荷分离,实现加速光催化磺胺嘧啶的降解
https://mp.weixin.qq.com/s/odUJzxGWhYdFJe9vyYnYVA
山东大学何作利教授团队Chinese J. Catal.:光催化耦合技术在废水处理领域的研究进展
https://mp.weixin.qq.com/s/zlb9mt2vvUta05vEQjLhJQ
山东大学王曙光、何作利团队Small综述:2D/2D异质结光催化剂界面构筑与优化
https://mp.weixin.qq.com/s/xCjrxK8d0mzRv5fjY1cTOw
https://mp.weixin.qq.com/s/xFarME3-KtBeuvmO-hsDAA
https://mp.weixin.qq.com/s/L_8iBfsbJHXjw4kwiQAQqQ
何作利研究员在异质结光催化领域获得系列成果
https://www.view.sdu.edu.cn/info/1021/173904.htm
https://mp.weixin.qq.com/s/M33iWV9k-n5gitbH8ADl3g
https://wx.sdu.edu.cn/wechat/site/info.jsp?wechat=1000105&newstype=local&id=36637
山东大学何作利教授CEJ: 光生载流子空间分离提高CdLa2S4/ZnIn2S4-S型异质结的光催化活性
https://mp.weixin.qq.com/s/iK7uccwrFwrILKJVuOjJwQ
https://mp.weixin.qq.com/s/zsSv82IQTFkU144UqGeYjg
山东大学何作利课题组:新型TiO2/TPU光催化复合纤维织物
https://mp.weixin.qq.com/s/NQamiN8JX9tNVk0psrU6mg
柔性织物湿度传感器|中科院苏州纳米所周庚衡研究员Materials Today Nano:超快、高灵敏度、柔性织物湿度传感器
https://mp.weixin.qq.com/s/IeHzjZTPi1Wkjei1yO9zHw
https://www.sensorexpert.com.cn/article/52508.html
Small:一维/二维异质结光催化剂的构筑、性能及其在环境中的应用
https://mp.weixin.qq.com/s/dsFAuXup-SnNVTCKjWijxQ
山大何作利、王曙光课题组Solar RRL综述:液相法原位构筑g-C3N4异质结光催化剂及其在环境中的应用
https://mp.weixin.qq.com/s/VuQVWcSWQGwjsG0CfOp34A
山东大学何作利教授团队《Appl. Surf. Sci.》:TiB2-TiO2@g-C3N4核壳结构高效光催化降解有机污染物
https://mp.weixin.qq.com/s/YtMQ7ar8Wnr7DMWVWl_GMw
山大何作利教授团队《ACS Appl. Nano Mater.》:MgB4类MXene纳米片用于光催化产氢