李逸兴，工学博士，东北大学材料科学与工程学院副教授，九三学社社员，2020年7月毕业于东北大学材料科学与工程学院。

目前在秦高梧教授负责的金属型线材研究中心从事研究。

主要研究方向为：1. 磁-电复合型电磁波吸收材料设计与研究；2. 高频软磁材料制备与研究； 3. 六角铁氧体制备与性能研究。

https://publons.com/researcher/5297414/yixing-li

https://www.scopus.com/authid/detail.uri?authorId=57119636100

目前以第一/通讯作者发表SCI论文20余篇，授权专利7件，代表性论文如下：

2024年：

（1）R. Z. Zhao, T. Gao, Y. X. Li*, Z. Sun, Z. Y. Zhang, L. Z. Ji, C. L. Hu, X. L. Liu, Z. H. Zhang, X. F. Zhang*, G. W. Qin, Highly anisotropic Fe3C microflakes constructed by solid-state phase transformation for efficient microwave absorption, Nat. Commun. (2024) 15, 1497.

2023年：

（1）Y. X. Li, L. L. Yang, Y. J. Liao, R. Z. Zhao, L. Z. Ji, R. Su, D. K. Xu*, F. H. Wang, Photothermal Heating-Assisted Superior Antibacterial and Antibiofilm Activity of High-Entropy-Alloy Nanoparticles. Adv. Funct. Mater. (2023) 33(35), 2302712.

（2）J. C. Ruan, Z. X. Chang, H. W. Rong*, T. S. Alomar, D. P. Zhu, N. AlMasoud, Y. J. Liao, R. Z. Zhao, X. Y. Zhao, Y. X. Li*, B. B. Xu, Z. H. Guo*, Z. M. El-Bahy, H. D. Li, X. F. Zhang, S. B. Ge*, High-conductivity nickel shells encapsulated wood-derived porous carbon for improved electromagnetic interference shielding. Carbon (2023) 213, 118208.

（3）廖怡君, 马艺, 冀连泽, 戎华威, 李逸兴*, 张雪峰. 高熵合金纳米颗粒研究进展. 中国科学: 技术科学 (2023) 53, doi: 10.1360/SST-2023-0057. Y. J. Liao, Y. Ma, L. Z. Ji, H. W. Rong, Y. X. Li*, X. F. Zhang*, Research advances in high-entropy alloy nanoparticles (in Chinese). Sci. Sin. Tech. (2023) 53, doi: 10.1360/SST-2023-0057.

2022年：

（1）Y. J. Liao, Y. X. Li*, R. Z. Zhao, J. Zhang, L. Z. Zhao, L. Z. Ji, Z. Y. Zhang, X. L. Liu, G. W. Qin, X. F. Zhang*, High-entropy-alloy nanoparticles with ultra-mixed 21 elements for efficient photothermal conversion. Natl. Sci. Rev. (2022) 9(6), nwac041.

    （2）Y. X. Li, Y. J. Liao, L. Z. Ji, C. L. Hu, Z. H. Zhang, Z. Y. Zhang, R. Z. Zhao, H. W. Rong, G. W. Qin, X. F. Zhang*, Quinary High-entropy-alloy@graphite nanocapsules with tunable interfacial impedance matching for optimizing microwave absorption. Small (2022) 18(4), 2107265. (Front Cover)

    （3）T. Gao, R. Z. Zhao, Y. X. Li*, Z. Y. Zhu, C. L. Hu, L. Z. Ji, J. Zhang, X. F. Zhang*, Sub-Nanometer Fe clusters confined in Carbon Nanocages for Boosting Dielectric Polarization and Broadband Electromagnetic Wave Absorption. Adv. Funct. Mater. (2022) 32(31), 2204370. (Inside Back Cover)

  （4）Y. J. Liao, Y. X. Li*, L. Z. Ji, X. L. Liu, X. Y. Zhao, H. W. Rong, D. K. Xu, G. W. Qin, X. F. Zhang, Confined high-entropy-alloy nanoparticles within graphitic shells for synergistically improved photothermal conversion. Acta Mater. (2022) 240, 118338.

  （5）Y. X. Li, Y. Ma, Y. J. Liao, L. Z. Ji, R. Z. Zhao, D. P. Zhu, X. Hu, G. W. Qin, H. W. Rong*, X. F. Zhang, High-Entropy-Alloy-Nanoparticles Enabled Wood Evaporator for Efficient Photothermal Conversion and Sustainable Solar Desalination. Adv. Energy Mater. (2022) 12(47), 2203057.

  （6）M. L. Cheng, M. F. Ying, R. Z. Zhao*, L. J. Ji, H. X. Li, X. G. Liu, J. Zhang, Y. X. Li*, X. L. Dong, X. F. Zhang, Transparent and Flexible Electromagnetic Interference Shielding Materials by Constructing Sandwich AgNW@MXene/Wood Composites. ACS Nano (2022) 16(10), 16996-17007.

    （7）T. Gao, Z. Y. Zhang, Y. X. Li*, Y. J. Song, H. W. Rong, X. F. Zhang*, Solid-state reaction induced defects in multi-walled carbon nanotubes for improving microwave absorption properties. J. Mater. Sci. Technol. (2022) 108, 37-45.

（8）T. Gao, Y. Ma, L. Z. Ji*, Y, Zheng, Y. X. Li*, X. F. Zhang, Nickel‑coated wood‑derived porous carbon (Ni/WPC) for efficient electromagnetic interference shielding. Adv. Compos. Hybrid Mater. (2022) 5(3), 2328-2338.

（9）Y. X. Li*, S. Y. Yan, Z. Y. Zhang, Y. J. Liao, H. W. Rong*, R. Z. Zhao, G. W. Qin, Wood-Derived Porous Carbon/Iron Oxide Nanoparticle Composites for Enhanced Electromagnetic Interference Shielding. ACS Appl. Nano Mater. (2022) 5(6), 8537-8545.

2021年：

（1）Y. X. Li, Y. J. Liao, J. Zhang, E. H. Huang, L. Z. Ji, Z. Y. Zhang, R. Z. Zhao, Z. M. Zhang, B. Yang, Y. H. Zhang, B. Xu*, G. W. Qin, X. F. Zhang*, High-entropy-alloy nanoparticles with enhanced interband transitions for efficient photothermal conversion. Angew. Chem. Int. Ed. (2021) 60, 27113-27118.

    （2）H. H. Hu, Y. X. Li*, T. Gao, S. Y. Yan, S. T. Wu, S. Bandaru, Y. Zheng, G. W. Qin, X. F. Zhang*. Sulfur-doped wood-derived porous carbon for optimizing electromagnetic response performance. Nanoscale (2021) 13, 16084-16093.

（3）Z. Y. Zhang, Y. X. Li*, Y. J. Liao, H. W. Rong, W. T. Zhang, M. Zhang, G.W. Qin, X. F. Zhang, Synthesizing CNx heterostructures on ferromagnetic nanoparticles for improving microwave absorption property. Appl. Surf. Sci. (2021) 564, 150480.

2020年：

（1）Y. X. Li, X. Y. Chen, Q. Wei, W. W. Liu, Y. H. Zhang, G. W. Qin, Z. Shi, X. F. Zhang*, Oxygen-sulfur Co-substitutional Fe@C nanocapsules for improving microwave absorption properties. Sci. Bull. (2020) 65, 623-630.

（2）Y. X. Li, Y. Zheng, R. G. Liu, Y. Rao, R. Su, J. Y. Yu, X. G. Liu, P. F. Guan, J. J. Guo, X. F. Zhang*, G. W. Qin, Enhanced high-frequency microwave absorption in core-shell nanocapsules with atomic-scale oxygen substitutions. J. Appl. Phys. (2020) 127, 195107.

2019年及以前：

（1）Y. X. Li, T. Gao, W. T. Zhang, H. H. Hu, H. W. Rong, X. F. Zhang*, Fe@CNx nanocapsules for microwave absorption at gigahertz frequency. ACS Appl. Nano Mater. (2019) 2, 3648-3653.

（2）Y. X. Li, X. F. Liu, R. G. Liu, X. Y. Pang, Y. H. Zhang, G. W. Qin, X. F. Zhang*, Improved microwave absorption properties by atomic-scale substitutions. Carbon (2018) 139, 181-188.

（3）Y. X. Li, R. G. Liu, X. Y. Pang, X. N. Zhao, Y. H. Zhang, G. W. Qin, X. F. Zhang*, Fe@C nanocapsules with substitutional sulfur heteroatoms in graphitic shells for improving microwave absorption at gigahertz frequencies. Carbon (2018) 126, 372-381.

（4）Y. X. Li, Z. Mao, R. G. Liu, X. N. Zhao, Y. H. Zhang, G. W. Qin, X. F. Zhang*, Ultralight Fe@C nanocapsules/sponge composite with reversibly tunable microwave absorption performances. Nanotechnology (2017) 28, 325702.

（5）Y. X. Li, J. Y. Wang, R. G. Liu, X. N. Zhao, X. J. Wang*, X. F. Zhang*, G. W. Qin, Dependence of gigahertz microwave absorption on the mass fraction of Co@C nanocapsules in composite. J. Alloys Compd. (2017) 724, 1023-1029.

（6）X. F. Zhang*, Y. X. Li, R. G. Liu, Y. Rao, H. W. Rong, G. W. Qin, High-magnetization FeCo nanochains with ultrathin interfacial gaps for broadband electromagnetic wave absorption at gigahertz. ACS Appl. Mater. Interfaces (2016) 8, 3494-3498.

授权发明专利：

    （1）张雪峰，李逸兴，赵晓宁，李剑飞，周丽平，齐琦琦. 一种可外力调控的复合型微波吸收体及制备方法. 中国专利，2020-5-12, 授权号：ZL201710381944.1.

（2）张雪峰，郭家奇，李逸兴，廖怡君，张艳辉. 一种高熔点高熵软磁合金的制备方法. 中国专利，2022-1-28, 授权号：ZL202110308221.5.

（3）张雪峰，郑芸，李逸兴. 在木质基材料表面构建疏水涂层的电磁屏蔽材料制备工艺. 中国专利，2022-3-29, 授权号：ZL202011306735.9.

（4）张雪峰，李逸兴，冀连泽. 一种薄膜材料的多场耦合型微波性能测试平台. 中国专利，2022-5-20, 授权号：ZL202011311193.4.

（5）张雪峰，赵思洋，李逸兴，阮佳昌. 一种导电硅胶用镍包石墨复合粉体材料的制备方法. 中国专利，2022-5-13, 授权号：ZL202110301151.0.

（6）张雪峰，陈新宇，李逸兴，张政宇，孙卓. 一种仿珍珠贝电磁波吸收薄膜的制备方法. 中国专利，2022-6-17, 授权号：ZL202110290247.1.

（7）张雪峰，李逸兴，廖怡君，张政宇. 一种极度混溶的21元高熵合金纳米颗粒及其制备方法. 中国专利，2022-8-30, 授权号：ZL202111360437.2.

[1]   2016.9-2020.7

东北大学  |  材料学  |  工学博士学位  |  博士研究生毕业

[2]   2012.9-2016.6

东北大学  |  材料科学与工程  |  工学学士学位  |  大学本科毕业

[1]   2023.1-至今

东北大学  |  材料科学与工程学院  |  副教授

[2]   2020.8-2022.12

东北大学  |  材料科学与工程学院  |  讲师

[1]  邮编： 4f8334c94896bf3162dde966b6cfb5b7cfbbd54f325874609a0c6545de95f7628763ee1ebc689cc4e6ff1ffdd636887abd463087e81292aac127d59d008164bffeba600e32deb37297537347ae479e702689ccf9ff3ed16f63c323b908c41badeac3e78a45cd43f6f946121ec854113671a853ca138d32da1b0ccd819edd69fd

[3]  通讯/办公地址： 107ccee80dc235a82195d86aaa4bc5af5c141243801f80380178c96eb42720102c1d19321ab3a3ba589f897b67221deae9cf4773deee57815aaf69222851b42cdda4199cac47c4482d4c654a791b96a62507c17f4e35b0e1e76d1ed6348d08066e01a310250b06901070ffc95ce423201d79f237aadf861ccb081c28e6cef44c

[6]  邮箱： 1076c47dd615cab239db298af35532eaa0126c12ea246fef494269f67831573c9ab20258136f8a598e01f441d1915a994524af9f0d50e4958a2745567db46024739a6e7a60906eef48dfcec0e9141a9b82d61fd2166a0cd207adfbc149d3aaf4b2003714af3fc24cd058f96df32e4812ed326d5d57b7db0faab03b603c0a81f4