张利伟(1979.2-)，博士(后)，教授，硕士生导师，主要从事人工电磁材料、二维材料、表面等离激元、复杂系统相变等方面的研究。

个人主页：https://www.scholarmate.com/P/zlw

一、教育背景:

1998.09-2002.07，郑州大学物理学院，物理学，获理学学士学位。

2002.09-2005.07，郑州大学物理学院，材料物理与化学，获工学硕士学位。

2005.09-2008.08，同济大学物理科学与工程学院，凝聚态物理，获理学博士学位。

2009.11-2011.10，同济大学材料科学与工程博士后流动站, 功能材料与器件，博士后。

2016.03-2017.02，University of Southamptonn, UK, Optoelectronics, Academic Visitor.

二、工作经历:

2008.08-2020.12，河南理工大学，讲师，副教授，太行学者，内聘教授。

2021.01至今，安庆师范大学数理学院，教授。

三、主讲课程

光学，热学，电磁学，大学物理，物理实验

四、实践教学：

1. 指导学生(施瑞等)参加2023年第九届全国大学生物理实验竞赛获国家级一等奖(2023.11)

2. 指导学生(梁陈等)参加2022年第八届全国大学生物理实验竞赛获国家级一等奖(2022.12)

3. 指导学生(宋爽等)参加2021年第七届全国大学生物理实验竞赛获国家级三等奖(2021.12)

4. 指导学生(未明)参加2023年安徽省大学生力学竞赛荣获省二等奖(2023.10)

5. 指导学生(施瑞等)参加2023年第六届中国大学生物理学术竞赛（华东赛区）荣获三等奖（2023.07）

6. 指导学生(梁陈等)参加2022年第五届中国大学生物理学术竞赛（华东赛区）荣获三等奖（2022.07）

7. 指导学生(王泽弘等)参加2021年第四届中国大学生物理学术竞赛（华东赛区）荣获三等奖（2021.06）

五、荣获奖励：

1. 2018年，光电功能器件的设计与制备，河南省教育厅科技成果一等奖，第一

2. 2017年，光栅器件与物理，河南省教育厅科技成果二等奖，第二

3. 2015年，河南省教育系统教学技能竞赛二等奖

4. 2013年，河南省教育厅学术技术带头人

5. 2012年，河南省高等学校青年骨干教师

6.2009年，同济大学优秀博士学位论文

六、研究课题：

1. 主持国家自然科学基金-联合基金，可重构超材料基二维过渡金属硫化物的光电特性及纳米器件研究(U1804165).

2. 主持国家自然科学基金-青年基金，各向异性特异材料对电磁波脉冲调控作用的研究(10904032).

3. 主持安徽省高校科研计划项目，激光诱导相变超表面的多物理元胞自动机模拟与实验研究(2023AH050488).

4. 主持中国博士后科学基金，基于各向异性特异材料的界面模和波导模的理论与实验研究(20100480629).

5. 主持河南省教育厅科学技术研究重点项目，特异材料复合结构中的能量输运及类量子现象研究(14A140011).

6. 主持河南省高校青年骨干教师计划项目，单负特异材料及其复合结构的电磁特性与应用研究(2012GGJS-060).

7. 主持河南省教育厅自然科学基金，电磁波在单负材料结构中的输运与控制(2010B140005).

8. 参与国家自然科学基金，石墨烯基二氧化钒薄膜的相变调控及同步辐射研究(11405045)，第二.

9. 参与国家自然科学基金，锑烯基异质结自旋电子结构的调控(11804081)，第二.

10. 参与安徽省高校科研计划项目，基于光学Tamm态的一维光子晶体生物传感器研究(2022AH051041)，第二.

11. 参与河南省高等学校重点科研项目，基于类磷烯量子自旋霍尔绝缘体的理论计算(19A140009)，第二.

12. 参与河南省高等学校重点科研项目，双原子层二维磷化碳光电特性的理论研究(18A140018)，第二.

七、主要代表论文：

1. X.Huang, L.W.Zhang*, X.L.Chen, et al, Urine Glucose Concentration Detection Biosensor Using One-Dimensional Photonic Crystals with Periodical and Fibonacci Sequences Based on Tamm Plasmon Resonance, Phys. Scr. 99, 075540 (2024).

2. Q.Wang, L.W.Zhang*, P. Cencillo-Abad, et al, Theoretical investigation of bidirectional and unidirectional dual-band absorption in one dimensional Octonacci sequences controlled by Dirac semimetal and Vanadium dioxide, Phys. Lett. A 512, 129589 (2024).

3. P.L.Hong, M.F.Yi, L.W.Zhang, et al, High-quality flatband resonances in few-cell moiré superlattices by band-offset tuning, Appl. Phys. Lett. 124, 181107 (2024).

4. X. Huang, L.W.Zhang*, X.L.Chen, One-dimensional photonic crystal biosensor based on Tamm plasmon resonance for malaria diagnosis in the short wavelength infrared band, Plamonics, 100, 165304 (2023).

5. L.W.Zhang, W.F.Liu, P. Cencillo-Abad, et al, A Tunable broadband polarization-independent metamaterial terahertz absorber based on VO2 and Dirac Semimetal, Opt. Commun. 542, 129602 (2023).

6. W.F.Liu, J.Fu, L.Zheng, L.W.Zhang*, et al, Quantum correlations and entanglement in electromagnetically induced transparency system, Int. J. Theor. Phys. 62, 127 (2023).

7. Q.Wang, L.W.Zhang*, X.Cai, et al, Tunable angle-selective optical transparency induced by photonic topological transition in dirac semimetals based hyperbolic metamaterials, Opt. Express. 30, 23102 (2022).

8. L.W.Zhang, R.F.Waters, K. F. MacDonald, N. I. Zheludev, Cellular automata dynamics of nonlinear optical processes in a phase-change materials, App. Phys. Rev. 8, 011404 (2021).

9. L.W.Zhang, X.L.Cai, Q.Wang, Bandwidth convertible mid-infrared absorption of one-dimensional quasi-periodic system containing Dirac semimetals, Opt. Commun. 482, 126603 (2021).

10. L.W.Zhang, Q. Wang, W.W.Meng, Dual-band absorption enhancement of monolayer transition metal dichalcogenides in metamaterials, Optoelectronics Lett. 17, 0412 (2021).

11. X.L.Cai, X.T.Jia, Y.J.Liu, L.W.Zhang*, et al, Enhanced Carrier Mobility and Tunable Electronic Property in α-Tellurene monolayer via α-Tellurene and h-BN Heterostructure, Phys. Chem. Chem. Phys. 22, 6434 (2020).

12. L.W.Zhang, W.Y.Yu, Q.Wang, et al, Electronic and hyperbolic dielectric properties of ZrS2/HfS2 heterostructures, Phys. Rev. B 100, 165304 (2019).

13. Q.Wang, L.W.Zhang*, Tunable narrow terahertz absorption of one-dimensional photonic crystals embedded with Dirac semimetal-dielectric defect layers, Appl. Opt. 58, 8486 (2019).

14. Q.Wang, X.Wang, L.W.Zhang*, et al, Tunable defect modes of one-dimensional photonic crystals containing a Dirac semimetal-based metamaterial defect layer, Appl. Opt. 58, 94 (2019).

15. X.T.Jia, P.Wu, L.W.Zhang, et al, Basic circuit element for the implementation of base-3 and base-4 algorithms realized by an asymmetric MgO-based double-barrier magnetic tunnel junction, Phys. Rev. B 99, 174413 (2019).

16. L.W.Zhang, W.Y.Yu, J.Y.Ou, et al, Midinfrared one-dimensional photonic crystal constructed from two-dimensional electride material, Phys. Rev. B 98, 075434 (2018).

17. L.W.Zhang, X.L.Wang, W.T.Qiao, et al, Fano resonance and Rabi splitting in MDM side-coupled cavities systems, Opt. Commun. 421, 66 (2018).

18. L.W.Zhang, G.D.Wang, X.Han, et al, Transmission property of one-dimensional multilayer graphene dielectric stack, Optik, 127, 2030 (2016).

19. W.T.Qiao, D.Zhang, L.W.Zhang*, et al, Post-thermal annealing for enhancing photovoltaic performance of CdS/CdSe quantum dot co-sensitized TiO2 electrodes, J. Alloy. Compd. 658, 697 (2016).

20. W.S.Wang, L.W.Zhang*, L.Shang, et al, Experimental study of band-pass filter and slow wave effect in MDM channel based on a magnetic plasmonic analogue of EIT, J. Korean Phys.Soc. 67, 1544 (2015).

21. 乔文涛，龚健，张利伟*，等，梳状波导结构中石墨烯表面等离子体的传播性质，物理学报，64, 237301 (2015).

22. 龚健，张利伟*，陈亮，等，石墨烯基双曲色散特异材料的负折射与体等离子体性质，物理学报，64, 067301 (2015).

23. L.W.Zhang, L.Chen, Z.R. Zhang, et al, Extraordinary refraction and self-collimation properties of multilayer metallic-dielectric stratified structures, Physica B 457, 269 (2015).

24. Z.R.Zhang, L.W.Zhang, H.Li, et al, Plasmon induced transparency in a surface plasmon polariton waveguide with a comb line slot and rectangle cavity, Appl. Phys. Lett. 104, 231114 (2014).

25. L.W.Zhang, Z.R.Zhang, C.Y.Kang, et al, Tunable bulk polaritons of graphene-based hyperbolic metamaterials, Opt. Express. 22, 14022 (2014).

26. Z.R.Zhang, L.W.Zhang, P.F.Yin, et al, Coupled resonator induced transparency in surface plasmon polariton gap waveguide with two side-coupled cavities, Physica B 446, 55 (2014).

27. W.S.Wang, L.W.Zhang*, J.Ran, Experimental research of magnetic Plasmon polaritons in two dimensional metamaterials based on microstrip lines, Physica B 437, 24 (2014).

28. L.W.Zhang, W.T.Qiao, L.Chen, et al, Double defect modes of one-dimensional dielectric photonic crystals containing a single negative material defect, Optik, 125,1354 (2014).

29. L.W.Zhang, W.Y.Yu, J.Wang, et al, Self-collimation and slow light in one-dimensional quasi periodic structures containing single negative materials, Opt. Commun. 313,134 (2014).

30. L.W.Zhang, Y.Zhang, X.Chen, et al, Study on the tunneling mode in a sub-wavelength open cavity resonator consisting of single negative materials, IEEE Trans. Antennas. Propagat. 62, 504 (2014).

31. W.S.Wang, L.W.Zhang*, J.Ran, H.Zhao, Experimental research of the tunable magnetic plasmon polaritons waveguide filter in microwave band, Opt. Commun. 311, 201 (2013).

32. L.W.Zhang, J.Wang, L.He, et al, Tunneling times in a conjugate matched pair consisting of ε-negative and μ-negative materials, Physica B 431,127 (2013).

33. W.S.Wang, L.W.Zhang, K.Fang, et al, Experimental demonstration of EIT effect in the metamaterials surface plasmon-like channel, Opt. Commun. 292, 5 (2013).

34. L.W.Zhang, G.Q.Du, Y.W.Zhang, Time domain investigation of the tunneling modes in photonic heterostructure containing single negative materials, Appl. phys. A 109, 851 (2012).

35. 张利伟,赵玉,等,各向异性特异材料波导中表面等离子体的共振性质,物理学报, 61, 068401 (2012) .

36. L.W.Zhang, Y.W.Zhang, L.He, et al, Experimental study of the tunneling modes in photonic crystal heterostructure consisting of single-negative materials, Chin. Phys. Lett. 29, 064209 (2012).  

37. L.W.Zhang, Y.W.Zhang, X.D.Chen, et al, Energy transport in a metamaterial subwavelength open cavity resonator, Opt. Lett. 36, 2224 (2011).

38. L.W.Zhang, Y.W.Zhang, Y.P.Yang, et al, Experimental study of Rabi-type oscillation induced by tunneling modes in effective near-zero-index metamaterials, Phys. Rev. E 83, 046604 (2011).

39. L.W.Zhang, K.Fang, G.Q.Du, et al, Transmission properties of Fibonacci quasi-periodic one dimensional photonic crystals containing indefinite metamaterials, Opt. Commun. 284, 703 (2011).

40. G.Q.Du, L.W.Zhang, H.T.Jiang, Broadband and omnidirectional absorption in heterostructures with a highly absorptive metallic film and a dielectric Bragg reflector, J. Appl. Phys. 109, 063525 (2011).

41. L.W.Zhang, Y.W.Zhang, Y.H.Zhao, et al, Rabi splitting induced by a metamaterial plasmon cavity,  Opt. Express. 18, 25052 (2010).

42. L.W.Zhang, L.Yan, Y.H.Zhao, et al, The transmission properties of one dimensional photonic crystals containing anisotropic metamaterials, Chin. Phys. Lett. 27, 064101 (2010).

43. 张利伟，许静平，赫丽，等，含单负材料三明治结构的电磁隧穿特性，物理学报，59, 7863 (2010).

44. 张利伟，王佑贞，赫丽，等，基于传输线的单负材料双层结构的隧穿性质，物理学报，59, 6106 (2010).

45. L.W.Zhang, G.Q.Du, J.P.Xu, et al, Double-channeled omnidirectional filtering properties of the sandwich structures composed of single-negative materials, Eur.Phys.J.Appl.Phys. 47, 10501 (2009).

46. L.W.Zhang, Y.W.Zhang, L.He, et al, Non-Bragg bandgaps of quasi-one-dimensional comb likes tructures composed of positive and negative index materials, Eur. Phys.J. D. 55, 155 (2009).

47. L.W.Zhang, Y.W.Zhang, L.He, et al, Experimental investigation on zero-Øeff gaps of photonic crystals containing single-negative materials, Eur. Phys.J. B 62,1 (2008).

48. L.W.Zhang, Z.G.Wang, et al, Experimental study of quasi-one-dimensional comb-like photonic crystals containing metamaterials, Opt. Commun. 281, 3681 (2008).

49. L.W.Zhang, Y.W.Zhang, Y.P.Yang, et al, Experimental observation of Rabi splitting in effective (near) zero-index media in microwave regime, Phys. Rev. E 78, R035601 (2008).

50. L.W.Zhang, Y.W.Zhang, L.He, et al, Zero-n gaps of photonic crystals consisting of positive and negative index materials in microstrip transmission lines. J. Phys D: Appl. Phys. 40, 2579 (2007).

51. L.W.Zhang, Y.W.Zhang, L.He, et al, Experimental study of photonic crystals consisting of ε-negative and μ-negative materials. Phys. Rev. E 74, 056615 (2006).