李海增 山东大学主页平台管理系统

李海增，山东大学前沿交叉科学青岛研究院和能源与动力工程学院双聘教授、博士生导师，SID显示未来之星青年领袖，青年泰山学者，首届山东省海外优青项目获得者，获得Wiley中国开放科学2022年度作者奖，任国产期刊Nano-Micro Letters (IF: 26.6)、Energy & Environmental Materials (IF: 15)、Materials Research Letters (IF:8.3)、Nano Materials Science (IF: 9.9)、Advanced Powder Materials (预计首个IF>10)、Frontiers of Physics (教育部主管、高等教育出版社主办期刊, IF:7.5)青年编委，国家自然科学基金、博士后面上基金评审专家。

李海增博士毕业于东华大学纤维材料改性国家重点实验室科技部重点领域创新团队、教育部创新团队(负责人：朱美芳院士)，师从王宏志教授。攻读博士学位期间获东华大学优博访学资助作为交换生加入美国国家发明家科学院院士、ACS Energy Letters副主编Pooi See Lee院士课题组进行联合培养。由于电致变色领域学科交叉的特点，李海增课题组目前的研究工作主要在山东大学三个二级学院(前沿交叉科学青岛研究院、能源与动力工程学院、化学与化工学院)、多个团队(能源与动力工程学院/前沿交叉科学青岛研究院刘林华杰青团队、化学与化工学院于伟泳杰青团队)内开展。目前课题组主要研究方向为电致变色光热调控器件，涉及内容包括：

① 红外发射率可调电致变色器件；

② 低成本电致变色显示技术；

③ 智能窗用柔性可裁剪电致变色贴膜；

④ 人体辐射热管理能源织物。

近五年，以一作或通讯作者在Joule、Advanced Materials (2篇)、Light: Science & Applications、Materials Today、Advanced Functional Materials、Advanced Energy Materials、Advanced Optical Materials、Nano-Micro Letters、Nano Energy、Nanophotonics、Nanoscale Horizons、ACS Applied Materials & Interfaces等主流杂志发表学术论文20余篇，其中多篇当选ESI热点论文和高被引论文。此外，李海增教授获授权中国发明专利3项，美国专利1项。

【代表性论文】

入职山大后文章：

[19] J. Hu, Y. Zhang, B. Xu, Y. Ouyang, Y. Ma, H. Wang, J. Chen*, H. Li*, XXXX for durable electrochromic devices, Chem. Comm., Submitted. (邀请论文, Nature Index Journal, 影响因子4.9）

[18] B. Xu, J. Chen*, P. Li, Y. Ouyang, Y. Ma, H. Wang*, H. Li*, Transparent Metal Oxide Interlayer Enabling Durable and Fast-switching Zinc Anode-Based Electrochromic Devices, Nanoscale, https://doi.org/10.1039/D3NR04902G. (邀请论文, 影响因子6.7）

[17] D. Ma, T. Yang, X. Feng, P. Wang, J. Huang, J. Wang*, H. Li*, Quadruple Control Electrochromic Devices Utilizing XXXXXX, Adv. Sci., Under Review. (邀请论文, 影响因子15.1）

[16] F. Zhao, B. Wang, J. Chen, S. Cao, Y. Yang*, W. W. Yu*, H. Li*, Hydrogel, the next-generation electrolyte for electrochromic devices, Physica Status Solidi (RRL) - Rapid Research Letters, DOI:10.1002/pssr.202300345. (邀请综述）

[15] Z. Song, B. Wang, W. Zhang, Q. Zhu*, A. Y. Elezzabi, L. Liu, W. W. Yu, H. Li*, Fast and stable zinc anode-based electrochromic displays enabled by bimetallically doped vanadate and aqueous Zn2+/Na+ hybrid electrolytes. Nano-Micro Lett., 2023, 15, 229.(邀请论文, 影响因子26.6)

[14] B. Wang, F. Zhao, W. Zhang, C. Li, K. Hu, L. Liu, W. W. Yu, A. Y. Elezzabi*, H. Li*, Inhibiting Vanadium Dissolution of Potassium Vanadate for Stable Transparent Electrochromic Displays. Small Sci., 2023, 2300046. (邀请论文, 影响因子12.7)

[13] F. Zhao, B. Wang, W. Zhang*, S. Cao, L. Liu, A. Y. Elezzabi, H. Li*, W. W. Yu*, Counterbalancing the interplay between electrochromism and energy storage for efficient electrochromic devices. Mater. Today, 2023, 66, 431. (邀请综述, 影响因子24.2) 

[12] B. Xu, J. Chen*, Z. Ding, J. Hu, Y. Zhang, H. Li*, H. Wang*, The Progress and Outlook of Multivalent lon-Based Electrochromism. Small Sci., 2023, 2300025. (邀请综述, 影响因子12.7) 

[11] J. Guo, Y. Liang, S. Zhang, D. Ma, T. Yang, W. Zhang, H. Li, S. Cao*, B Zou, Recent progress in improving strategies of metal oxide-based electrochromic smart window. Green Energy Res., 2023, 1, 100007. (山东大学主办能源类期刊)

[10] H. Liu, H. Zheng, X. Wang,* Q. Jia, L. Chen, S. Song, H. Li*, Efficient Overall Water-splitting Enabled by Tunable Electronic States of Vanadium-substituted P-Co3O4. Mater. Today Chem., 2023, 30, 101530.

[9] W. Zhang, H. Li*, A. Y. Elezzabi*, A Dual-Mode Electrochromic Platform Integrating Zinc Anode-Based and Rocking-Chair Electrochromic Devices. Adv. Funct. Mater., 2023, 33, 2300155. 

[8] E. Hopmann*, W. Zhang, H. Li, A. Y. Elezzabi, Advances in electrochromic device technology through the exploitation of nanophotonic and nanoplasmonic effects. Nanophotonics, 2023, 12, 637. 

[7] B. Wang, W. Zhang, F. Zhao, W. W. Yu, A. Y. Elezzabi*, L. Liu*, H. Li*, An overview of recent progress in the development of flexible electrochromic devices. Nano Materials Science, In Press.  (邀请综述, 影响因子9.9, 重庆大学主办国产期刊，ESCI, cite score 14.3)

[6] W. Zhang, H. Li*, A. Y. Elezzabi*, Nanoscale Manipulating Silver Adatoms for Aqueous Plasmonic Electrochromic Devices. Advanced Materials Interfaces, 2022, 9, 2200021.

[5] W. Zhang*, H. Li*, A. Y. Elezzabi, Electrochromic displays having two-dimensional CIE color space tunability. Advanced Functional Materials, 2022, 32, 2108341.

(Materials Views报道：https://mp.weixin.qq.com/s/ghg1XAiPIinqMVMtleofJQ 

解说科研项目报道：https://mp.weixin.qq.com/s/HtReuFrwRpfcXN6iVAmqKg  

化学与材料科学报道：https://mp.weixin.qq.com/s/7LvU7LMHn1FXT073v3LW-w  ）

[4] Y. Liang, S. Cao*, Q. Wei, R. Zeng, J. Zhao, H. Li*, W. W. Yu, B. Zou*,Reversible Zn2+ Insertion in Tungsten Ion Activated Titanium Dioxide Nanocrystals for Electrochromic Windows. Nano-Micro Letters, 2021, 13, 196. (高影响力国产期刊)

(Nano-Micro Letters公众号报道：https://mp.weixin.qq.com/s/N6dSjHlzXVhegDxD3KD6eg)

[3] A Fakharuddin*, H. Li*, F. D. Giacomo, T. Zhang, N. Gasparini*, A. Y. Elezzabi, A. Mohanty, A. Ramadoss, J. Ling, A. Soultati, M. Tountas, L. Schmidt-Mende, P. Argitis, R. Jose, M. K. Nazeeruddin, A. R. B. M. Yusoff*, M. Vasilopoulou*, Fiber-shaped electronic devices. Advanced Energy Materials, 2021, 2101443. (合作综述)

[2] K. Wang, Q. Meng, Q. Wang, W. Zhang, J. Guo, S. Cao*, A. Y. Elezzabi, W. W. Yu, L. Liu, H. Li*, Advances in Energy Efficient Plasmonic Electrochromic Smart Windows Based on Metal Oxide Nanocrystals. Advanced Energy and Sustainability Research, 2021, DOI:10.1002/aesr.202100117. (邀请综述)

(当选为Cover，

）

[1] W. Zhang, H. Li*, W. W. Yu, A. Y. Elezzabi*, Emerging Zn anode-based electrochromic devices. Small Science, 2021, DOI:10.1002/smsc.202100040. (邀请综述)

(Materials Views报道：https://www.materialsviewschina.com/2021/10/57350/）

入职山大前文章：

[1] H. Li*, C. J. Firby, A. Y. Elezzabi*, Rechargeable aqueous hybrid Zn2+/Al3+ electrochromic batteries. Joule, 2019, 3, 2268. (SCI, IF=29.155, ESI热点论文、高被引论文)

(能源学人报道：https://nyxr-home.com/25609.html)

[2] W. Zhang, H. Li*, W. W. Yu, A. Y. Elezzabi*, Transparent inorganic multicolour displays enabled by zinc-based electrochromic devices. Light: Science & Applications, 2020, 9, 121. (SCI, IF=13.714, 国产领军期刊)

(美国科学促进会AAAS报道: https://www.eurekalert.org/pub_releases/2020-07/lpcc-tim071420.php.

Phys.org报道: https://phys.org/news/2020-07-transparent-inorganic-multicolour-enabled-zinc-based.html.

中国光学报道: https://mp.weixin.qq.com/s/k90KnCtIEG4W_p5CLZXFjg. 

入选LSA10周年"光学与光子学"Collection: https://www.nature.com/collections/hhajgbdbdh  )

[3] H. Li*, W. Zhang, A. Y. Elezzabi*, Transparent zinc-mesh electrodes for solar-charging electrochromic windows. Advanced Materials, 2020, 32, 2003574. (SCI, IF=27.398)

[4] H. Li*, L. McRae, C. J. Firby, M. Al-Hussein, A. Y. Elezzabi*, Rechargeable aqueous electrochromic batteries utilizing Ti-substituted tungsten molybdenum oxide based Zn2+ ion intercalation cathodes. Advanced Materials, 2019, 31, 1807065. (SCI, IF=27.398, ESI高被引论文)

[5] H. Li*, L. McRae, C. J. Firby, A. Y. Elezzabi*, Nanohybridization of molybdenum oxide with tungsten molybdenum oxide nanowires for solution-processed fully reversible switching of energy storing smart windows. Nano Energy, 2018, 47, 130. (SCI, IF=16.602)

(LaserFocusWorld杂志在 Optics以及Detectors & Imaging专栏分别作了重点报道: https://www.laserfocusworld.com/optics/article/16555300/transparent-molybdenum-oxidebased-smart-windows-store-energy-like-a-battery;

https://www.laserfocusworld.com/detectors-imaging/article/16571711/molybdenum-smart-windows-store-energy-like-a-battery.)

[6] W. Zhang, H. Li*, E. Hopmann, A. Y. Elezzabi*, Nanostructured inorganic electrochromic materials for light applications. Nanophotonics, 2020, 10, 825. (SCI, IF=7.491,邀请综述)

[7] H. Li*, A. Y. Elezzabi, Simultaneously enabling dynamic transparency control and electrical energy storage via electrochromism. Nanoscale Horizons, 2020, 5, 691. (SCI, IF=9.927) (文章当选Nanoscale Horizons Most Popular Articles）

[8] W. Zhang, H. Li*, M. Al-Hussein, A. Y. Elezzabi*, Electrochromic battery displays with energy retrieval functions using solution-processable colloidal vanadium oxide nanoparticles. Advanced Optical Materials, 2020, 8, 1901224. (SCI, IF=8.286)

[9] H. Li*, L. McRae, A. Y. Elezzabi*, Solution-processed interfacial PEDOT:PSS assembly into porous tungsten molybdenum oxide nanocomposite films for electrochromic applications. ACS Applied Materials & Interfaces, 2018, 10, 10520. (SCI, IF=8.758)

[10] W. Zhang, H. Li*, C. J. Firby, M. Al-Hussein, A. Y. Elezzabi*, Oxygen-vacancy-tunable electrochemical properties of electrodeposited molybdenum oxide films. ACS Applied Materials & Interfaces, 2019, 11, 20378. (SCI, IF=8.758)

[11] H. Li, J. Li, C. Hou*, D. Ho*, Q. Zhang, Y. Li, H. Wang*, Solution-processed porous tungsten molybdenum oxide electrodes for energy storage smart windows. Advanced Materials Technologies, 2017, 2, 1700047. (SCI, IF=5.969)

[12] H. Li, C. Chen, M. Cui, G. Cai, A. Eh, P. S. Lee*, H. Wang*, Q. Zhang, Y. Li*, Spray coated ultrathin films from aqueous tungsten molybdenum oxide nanoparticle ink for high contrast electrochromic applications. Journal of Materials Chemistry C, 2016, 4, 33. (SCI, IF=7.059)

[13] H. Li, J. Wang, Q. Shi, M. Zhang, C. Hou*, G. Shi, H. Wang*, Q. Zhang, Y. Li, Q. Chi*, Constructing three-dimensional quasi-vertical nanosheet architectures from self-assemble two-dimensional WO3·2H2O for efficient electrochromic devices. Applied Surface Science, 2016, 380, 281. (SCI, IF=6.182)

[14] H. Li, G. Shi, H. Wang*, Q. Zhang, Y. Li *, Self-seeded growth of nest-like hydrated tungsten trioxide film directly on FTO substrate for highly enhanced electrochromic performance. Journal of Materials Chemistry A, 2014, 2, 11305. (SCI, IF=11.301)