个人信息Personal Information
副教授
博士生导师
硕士生导师
性别:男
出生日期:1987-08-21
毕业院校:大连理工大学
学位:博士
所在单位:物理学院
电子邮箱:yzliang@dlut.edu.cn
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1、表面等离激元纳米结构传感器
2、微纳结构空间光场和光谱调控
3、基于表面等离激元纳米传感芯片的生化检测仪器开发
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1. Yuzhang Liang, Wenli Cui, Lixia Li, Zhiyong Yu, Wei Peng, and Ting Xu*, “Large‐Scale Plasmonic Nanodisk Structures for a High Sensitivity Biosensing Platform Fabricated by Transfer Nanoprinting,” Advanced Optical Materials, 7, 201801269, 2019. (Cover Paper) (IF: 7.125)
2. Yuzhang Liang# , Zhiyong Yu# , Lixia Li, and Ting Xu*, “A self- assembled plasmonic optical fiber nanoprobe for label-free biosensing,” Scientific Reports, 9, 7379, 2019. (IF: 4.011)
3. 梁瑜章,徐挺*,“表面等离激元纳米阵列结构传感器的集成化和小型化研究,” 物理,48(1), 22-28, 2019. (国内核心)
4. Yuzhang Liang, Lixia Li, Mengdi Lu, Huizhen Yuan, Zhongwen Long, Wei Peng, and Ting Xu*, “Comparative investigation of sensing behaviors between gap and lattice plasmon modes in metallic nanoring array,” Nanoscale, 10(2), 548-555, 2018. (Cover Paper) (IF: 6.97)
5. Yuzhang Liang, Hui Zhang, Wenqi Zhu, Amit Agrawal, Henri Lezec, Lixia Li, Wei Peng, Yi Zou, Yanqing Lu*, and Ting Xu*, “Subradiant dipolar interactions in plasmonic nanoring resonator array for integrated label-free biosensing,” ACS Sensors, 2(12), 1796-1804, 2017. (IF: 6.944)
6. Yuzhang Liang, Mengdi Lu, Shuwen Chu, Lixia Li, and Wei Peng*, “Tunable plasmonic resonances in the hexagonal nanoarrays of annular aperture for biosensing,” Plasmonics, 11(1), 205-212, 2016. (IF: 2.926)
7. Yuzhang Liang, Wei Peng*, Lixia Li, Siyu Qian, and Qiao Wang, “Tunable plasmonic resonances based on elliptical annular aperture arrays on conducting substrates for advanced biosensing,” Optics Letters, 40(16): 3909-3912, 2015. (IF: 3.866)
8. Yuzhang Liang, Si Zhang, Xun Cao, Yanqing Lu, and Ting Xu*, “Free-standing plasmonic metal-dielectric-metal bandpass filter with high transmission efficiency,” Scientific Reports, 7, 4357, 2017. (IF: 4.011)
9. Yuzhang Liang, Zhiyong Yu, Ningjuan Ruan, Qian Sun, and Ting Xu*, “Freestanding optical negative-index metamaterials of green light,” Optics Letters, 42(16), 3239-3242, 2017. (IF: 3.866)
10. Yuzhang Liang, Ningjuan Ruan, Si Zhang, Zhiyong Yu, and Ting Xu*, “Experimental investigation of extraordinary optical behaviors in freestanding plasmonic cascade grating at visible frequency,” Optics Express, 26(3), 3271-3276, 2018. (IF: 3.561)
11. Yuzhang Liang, Wei Peng*, Mengdi Lu, and Shuwen Chu, “Narrow-band wavelength tunable filter based on asymmetric double layer metallic grating,” Optics Express, 23(16), 14434-14445, 2015. (IF: 3.561)
12. Yuzhang Liang, Wei Peng*, Rui Hu, and Lingxiao Xie, “Extraordinary optical properties in the subwavelength metallodielectric free-standing grating,” Optics Express, 22(16), 19484-19494, 2014. (IF: 3.561)
13. Yuzhang Liang, Wei Peng*, Rui Hu, and Mengdi Lu, “Symmetry-reduced double layer metallic grating structure for dual-wavelength spectral filtering,” Optics Express, 22(10), 11633-11645, 2014. (IF: 3.561)
14. Yuzhang Liang, Wei Peng*, Rui Hu, and Helin Zou, “Extraordinary optical transmission based on subwavelength metallic grating with ellipse walls,” Optics Express, 21(5), 6139-6152, 2013. (IF: 3.561)
15. Yuzhang Liang and Wei Peng*, “Theoretical study of transmission characteristics of Sub-wavelength Nano-structured metallic grating,” Applied Spectroscopy, 67(1), 49-53, 2013. (IF: 2.064)
16. Qingbin Fan# , Wenqi Zhu# , Yuzhang Liang#, Pengcheng Huo, Cheng Zhang, Amit Agrawal, Kun Hong, Xiangang Luo, Yanqing Lu, Chengwei Qiu*, Henri Lezec*, and Ting Xu*, “Broadband generation of photonic spin-controlled arbitrary accelerating light beams in the visible,” Nano Letters, 19(2), 1158-1165, 2019. (# Contributed equally to this work) (IF: 12.279)
17. Jiaxing Wang# , Yuzhang Liang# , Pengcheng Huo, Daopeng Wang, Jun Tan, and Ting Xu*, “Large-scale broadband absorber based on metallic tungsten nanocone structure,” Applied Physical Letters, 111(25), 251102, 2017. (# Contributed equally to this work) (IF: 3.521)
18. Lixia Li*, Yuzhang Liang*, Wei Peng, and Yufang Liu, “Fano-like resonances in the binary elliptical nanoring resonator array,” Optical Materials Express, 8(8), 2131-2139, 2018. (Corresponding Author) (IF: 2.673)
19. Wei Peng*, Yuzhang Liang, Lixia Li, and Jean-Francois Masson, “Metallic nanowire array-polymer hybrid film for surface plasmon resonance sensitivity enhancement and spectral range enlargement,” Plasmonics, 9(2), 319-326, 2014. (IF: 2.936)
20. Wei Peng*, Yuzhang Liang, Lixia Li, Yun Liu, and Jean-Francois Masson, “Generation of multiple plasmon resonances in a nanochannel,” IEEE Photonics Journal, 5(5), 4500509, 2013. (IF: 2.729)
21. Lei Feng, Pengcheng Huo, Yuzhang Liang, and Ting Xu, “Photonic Metamaterial Absorbers: Morphology Engineering and Interdisciplinary Applications,” Advanced Materials, 2019. (In Press) (Review) (IF: 25.809)
22. Maxime Couture, Yuzhang Liang, Hugo-Pierre Poirier Richard, Rita Faid, Wei Peng*, and Jean-Francois Masson*, “Tuning the 3D plasmon field of nanohole arrays,” Nanoscale, 5(24), 12399-12408, 2013. (IF: 6.97)
23. Pengcheng Huo, Yuzhang Liang, Si Zhang, Yanqing Lu, and Ting Xu*, “Angular optical transparency induced by photonic topological transitions in metamaterials,” Laser & Photonics Reviews, 12(8), 1700309, 2018. (IF: 9.056)
24. Siyu Qian, Yuzhang Liang, Jie Ma, Yang Zhang, Jianzhang Zhao*, and Wei Peng*, “Boronic acid modified fiber optic SPR sensor and its application in saccharide detection,” Sensors and Actuators B: Chemical, 220, 1217-1223, 2015. (IF: 6.393)
25. Lixia Li, Yuzhang Liang, Jianye Guang, Wenli Cui, Xinpu, Zhang, Jean-Francois Masson, Wei Peng*, “Dual Kretschmann and Otto configuration fiber surface plasmon resonance biosensor,” Optics Express, 25(22), 26949-26956, 2017. (IF: 3.561)
26. Mengdi Lu, Yuzhang Liang, Siyu Qian, Lixia Li, Zhengguo Jing, Jean-Feancois Masson, Wei Peng*, “Optimization of Surface Plasmon Resonance Biosensor with Ag/Au Multilayer Structure and Fiber-Optic Miniaturization,” Plasmonics, 12(3), 663-673, 2017. (IF: 2.926)
27. Lixia Li, Yuzhang Liang, Qiang Liu, and Wei Peng*, “Dual-channel fiber-optic biosensor for self-compensated refractive index measurement,” IEEE Photonics Technology Letters, 28(19), 2110-2113, 2016. (IF: 2.533)
28. Wenli Cui, Yuzhang Liang, Qiao Wang, Yun Liu, Lixia Li, Mengdi Lu, Zhidong Zhang, Jean-Francois Masson, and Wei Peng*, “Dual-channel and refractive index sensitivity based on a nanorod array,” Journal of The Optical Society of America B, 35(2), 237-243, 2018. (IF: 2.284)
29. Si Zhang, Yuzhang Liang, Qiang Jing, Zhenda Lu, Yanqing Lu*, and Ting Xu*, “Broadband enhancement of photoluminance from colloidal metal halide perovskite nanocrystals on plasmonic nanostructured surfaces,” Scientific Reports, 7, 14695, 2017. (IF: 4.011)
30. Pengcheng Huo, Yuzhang Liang, Si Zhang, and Ting Xu*, “Hybrid metasurface for broadband enhancing optical absorption and Raman spectroscopy of graphene,” Optical Materials Express, 7(10), 3591-3597, 2017. (IF: 2.673)
31. Zijie Zhang, Yuzhang Liang, Ting Xu*, “Research advances of hyperbolic metamaterials and metasurfaces,” Opto-Electronic Engineering, 44(3), 276-288, 2017.
32. Hua Gao*, Yuzhang Liang, Shujing Chen, Huiying Hao, and Wei Peng, “Achieving multi-order nearly perfect absorption based on phase resonance in a compound metallic grating,” Optics Communications, 331, 154-159, 2014. (IF: 1.961)
33. Rui Hu, Yuzhang Liang, Siyu Qian, and Wei Peng*, “Dual-band bandpass filter based on compound metallic grating waveguide structure,” Optics Communications, 336, 110-115, 2015. (IF: 1.961)
34. Pengcheng Huo, Si Zhang, Yuzhang Liang, Yanqing Lu, and Ting Xu*, “Hyperbolic Metamaterials and Metasurfaces: Fundamentals and Applications,” Advanced Optical Materials, 7, 1801616, 2019. (Review) (IF: 7.125)
35. Mengdi Lu, Long Hong, Yuzhang Liang, Benjamin Charron, Hu Zhu, Wei Peng*, Jean-Francois Masson*, “Enhancement of gold nanoparticle coupling with a 2D plasmonic crystal at high incidence angles,” Analytical Chemistry, 90(11), 6683-6692, 2018. (IF: 6.35)
36. Hui Zhang, Lei Feng, Yuzhang Liang, and Ting Xu*, “An ultra-flexible plasmonic metamaterial film for efficient omnidirectional and broadband optical absorption,” Nanoscale, 11(2), 437-443, 2019. (IF: 6.97)
37. Zijie Zhang, Zhiyong Yu, Yuzhang Liang, and Ting Xu*, “Dual-band nearly perfect absorber at visible frequencies,” Optical Materials Express, 8(2), 463-468, 2018. (IF: 2.673)
38. D. M. Li, X. Y. Kuang, H. Zhang, Y. Z. Liang, T. Xu, L. Y. Qing, Y. H. Zhu, S. Zhang, W. X. Wang, and W. Wang, “Experimental demonstration of high sensitivity refractive index sensing based on magnetic plasmons in a simple metallic deep nanogroove array,” Optics Express, 24(26), 34122-34130, 2018. (IF: 3.561)
39. Mengdi Lu, Wei Peng*, Qiang Liu, Yun Liu, Lixia Li, Yuzhang Liang, and Jean-Feancois Masson, “Dual channel multilayer-coated surface plasmon resonance sensor for dual refractive index range measurements,” Optics Express, 25(8), 8563-8570, 2017. (IF: 3.561)
40. Lixia Li, Xinpu Zhang, Yuzhang Liang, Jianye Guang, and Wei Peng*, “Dual-channel fiber surface plasmon resonance biological sensor based on a hybrid interrogation of intensity and wavelength modulation,” Journal of Biomedical Optics, 21(12), 127001, 2017. (IF: 6.97)
41. Mengdi Lu, Xinpu Zhang, Yuzhang Liang, Lixia Li, Jean-Feancois Masson, and Wei Peng*, “Liquid crystal filled surface plasmon resonance thermometer,” Optics Express, 24(10), 10904-10911, 2016. (IF: 3.561)
42. Lixia Li, Yuzhang Liang, Mengdi Lu, and Wei Peng*, “Fano resonances in thin metallic grating for refractive index sensing with high figure of merit,” Plasmonics, 11(1), 139-149, 2016. (IF: 2.926)
43. Yun Liu, Wei Peng*, Yuzhang Liang, Xinpu Zhang, Xinlei Zou, and Lujun Pan, “Fiber-optic Mach-Zehnder interferometric sensor for high-sensitivity high temperature,” Optics Communications, 300, 194-198, 2013. (IF: 1.961)
44. Yun Liu, Wei Peng*, Xinpu Zhang, Yuzhang Liang, Zhenfeng Gong, and Ming Han, “Fiber-Optic anemometer based on distributed bragg reflector fiber laser technology,” IEEE Photonics Technology Letters, 25(13): 1246-1249, 2013. (IF: 2.553)
45. Wenli Cui, Shuwen Chu, Yun Liu, Yuzhang Liang, and Wei Peng*, “Extraordinary optical transmission performances of nanosandwiched grating for wideband multi-function integration,” Plasmonics, 12(5), 1281-1288, 2017. (IF: 2.926)
46. Jiaxing Wang, Qinbin Fan, Si Zhang, Zijie Zhang, Hui Zhang, Yuzhang Liang, Xun Cao, and Ting Xu*, “Ultra-thin plasmonic color filters incorporating free-standing resonant membrane waveguides with high transmission efficiency,” Applied Physics Letters, 110(3), 031110, 2017. (IF: 3.521)
47. Qinbin Fan, Pengcheng Huo, Daopeng Wang, Yuzhang Liang, Yan Feng, Xu Ting*, “Visible light focusing flat lenses based on hybrid dielectric-metal metasurface reflector-arrays,” Scientific Reports, 7, 45044, 2017. (IF: 4.011)
48. Qinbin Fan, Daopeng Wang, Pengcheng Huo, Zijie Zhang, Yuzhang Liang, and Ting Xu*, “Autofocusing Airy beams generated by all-dielectric metasurface for visible light,” Optics Express, 25(8), 9285-9294, 2017. (IF: 3.561)
49. Yongmei Wang, XinYuan Fang, Zeyu Kuang, Huijun Wang, Dunzhao Wei, Yuzhang Liang, Qian-Jin Wang, Ting Xu, Yong Zhang*, and Min Xiao, “On-chip generation of broadband high-order Laguerre–Gaussian modes in a metasurface,” Optics Letters, 42(13), 2463-2466, 2017. (IF: 3.566)
50. Daopeng Wang, Qingbin Fan, Jiaxing Wang, Zijie Zhang, Yuzhang Liang, and Ting Xu*, “All-dielectric metasurface beam deflector at the visible frequencies,” Opto-Electronic Engineering, 44(1), 103-107, 2017. (EI)
51. Yanjie Wang, Shengwei Meng, Yuzhang Liang, Lixia Li, and Wei Peng*, “Fiber-Optic surface plasmon resonance sensor with multi-alternating metal layers for biological measurement,” Photonic Sensors, 3(3): 202-207, 2013. (EI)
52. Yuzhang Liang and Ting Xu, A Freestanding Optical Negative-index Metamaterials of Green-light, Progress In Electromagnetics Research Symposium, 2017 in Singapore. (邀请报告)
53. 梁瑜章,徐挺,大面积光学超构材料的制备和应用,第二届微纳光学技术与应用交流, 2018 武汉。 (代替合作导师徐挺做邀请报告)
54. 等离子体光学和纳米光学国际研讨会(iSPN2017),2017 大连。
55.徐挺,梁瑜章,Plasmonic nanostructure and their applications at optical frequencies, 第一届微纳光学技术与应用交流,2017 苏州。
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1、国家自然科学基金青年项目(No. 61705100)“表面等离激元纳米阵列在生化传感方面 的应用基础研究”2018.1-2020.12,进行
2、中国博士后科学基金面上资助(No. 2016M601773)“金属纳米结构集成生物传感器件 的关键技术研究”2016.9-2018.1,完成
3、江苏省博士后科研资助计划(No. 1601051C)“蓝紫光频段的负折射人工超材料的设计 和应用基础研究”2016.9-2018.1,完成
4、中央高校基本科研业务费(No. 021314380055)“表面等离激元纳米阵列在生化传感方 面的应用基础研究”2017.5-2018.5,完成