发表论文
[1] Chunlei Du. High-efficiency, stable and non-chemical-doped graphene-Si solar cells through interface engineering and PMMA antireflection. RSC Advances. 2016, [2] Mao, HongYan, Xia, LiangPing, Rao, XianHua, Cui, HongLiang, Wang, SiJiang, Deng, YunSheng, Wei, DongShan, Shen, Jun, Xu, HongMei, Du, ChunLei. A Terahertz Polarizer Based on Multilayer Metal Grating Filled in Polyimide Film. IEEE PHOTONICS JOURNAL[J]. 2016, 8(1): https://doaj.org/article/9aec658a833047738af80a23009ccc55.[3] Song, Xuefen, Wang, Mingjun, Wei, Dapeng, Liu, Dun, Shi, Haofei, Hu, Chenguo, Fang, Liang, Zhang, Wei, Du, Chunlei. Enhanced photoelectrochemical perporties of graphene nanowalls-CdS composite materials. JOURNAL OF ALLOYS AND COMPOUNDS[J]. 2015, 651: 230-236, https://www.webofscience.com/wos/woscc/full-record/WOS:000361830700034.[4] Chunlei Du. Direct growth of graphene nanowalls on the crystalline silicon for solar cells, Applied Physics Letters. Applied Physics Letters. 2015, [5] Yang, Jun, Wei, Dapeng, Tang, Linlong, Song, Xuefen, Luo, Wei, Chu, Jin, Gao, Tianpeng, Shi, Haofei, Du, Chunlei. Wearable temperature sensor based on graphene nanowalls. RSC ADVANCES[J]. 2015, 5(32): 25609-25615, https://www.webofscience.com/wos/woscc/full-record/WOS:000351354000099.[6] Jiao, Tianpeng, Liu, Jian, Wei, Dapeng, Feng, Yanhui, Song, Xuefen, Shi, Haofei, Jia, Shuming, Sun, Wentao, Dut, Chunlei. Composite Transparent Electrode of Graphene Nanowalls and Silver Nanowires on Micropyramidal Si for High-Efficiency Schottky Junction Solar Cells. ACS APPLIED MATERIALS & INTERFACES[J]. 2015, 7(36): 20179-20183, https://www.webofscience.com/wos/woscc/full-record/WOS:000361501700037.[7] Feng, Yanxiao, Zhang, Yuechuan, Ying, Cuifeng, Wang, Deqiang, Du, Chunlei. Nanopore-based Fourth-generation DNA Sequencing Technology. GENOMICS PROTEOMICS & BIOINFORMATICS[J]. 2015, 13(1): 4-16, http://lib.cqvip.com/Qikan/Article/Detail?id=664451414.[8] Jiao, Tianpeng, Wei, Dapeng, Liu, Jian, Sun, Wentao, Jia, Shuming, Zhang, Wei, Feng, Yanhui, Shi, Haofei, Du, Chunlei. Flexible solar cells based on graphene-ultrathin silicon Schottky junction. RSC ADVANCES[J]. 2015, 5(89): 73202-73206, https://www.webofscience.com/wos/woscc/full-record/WOS:000360552000088.[9] Luo, Wei, Chen, Weimin, Leng, Chongqian, Huang, Deping, Zhang, Yongna, Yang, Jun, Li, Zhancheng, Shi, Haofei, Du, Chunlei, Wang, Y, Du, C, Sasian, J, Tatsuno, K. Graphene composite anode for flexible polymer light emitting diode. OPTICAL DESIGN AND TESTING VInull. 2014, 9272: [10] Xia, LiangPing, Yang, Zheng, Yin, ShaoYun, Guo, WenRui, Du, JingLei, Du, ChunLei. Hole arrayed metal-insulator-metal structure for surface enhanced Raman scattering by self-assembling polystyrene spheres. FRONTIERS OF PHYSICS[J]. 2014, 9(1): 64-68, http://www.irgrid.ac.cn/handle/1471x/1108130.[11] Chunlei Du. Nanochannel fabrication by imprinting-induced crack. Applied Physics Letters. 2014, [12] Xia, Liangping, Yang, Zheng, Yin, Shaoyun, Guo, Wenrui, Li, Shuhong, Xie, Wanyi, Huang, Deping, Deng, Qiling, Shi, Haofei, Cui, Hongliang, Du, Chunlei. Surface enhanced Raman scattering substrate with metallic nanogap array fabricated by etching the assembled polystyrene spheres array. OPTICS EXPRESS[J]. 2013, 21(9): 11349-11355, http://www.irgrid.ac.cn/handle/1471x/1108127.[13] Tang, Linlong, Shi, Haofei, Gao, Hongtao, Du, Jinglei, Zhang, Zhiyou, Dong, Xiaochun, Du, Chunlei. An eigenvalue method to study the threshold behaviors of plasmonic nano-lasers. APPLIED PHYSICS B-LASERS AND OPTICS[J]. 2013, 113(4): 575-579, http://ir.ioe.ac.cn/handle/181551/6833.[14] Li, Chuanhao, Xia, Liangping, Gao, Hongtao, Shi, Ruiying, Sun, Chen, Shi, Haofei, Du, Chunlei. Broadband absorption enhancement in a-Si:H thin-film solar cells sandwiched by pyramidal nanostructured arrays. OPTICS EXPRESS[J]. 2012, 20(19): A589-A596, http://www.irgrid.ac.cn/handle/1471x/1108101.[15] Sun, Xiuhui, Xia, Liangping, Du, Jinglei, Yin, Shaoyun, Du, Chunlei. A hybrid long-range surface plasmon waveguide comprising a narrow metal stripe surrounded by the low-index dielectric regions. OPTICS COMMUNICATIONS[J]. 2012, 285(21-22): 4359-4363, http://dx.doi.org/10.1016/j.optcom.2012.06.055.[16] Tang, Linlong, Yin, Jinchan, Yuan, Guishan, Du, Jinglei, Gao, Hongtao, Dong, Xiaochun, Lu, Yueguang, Du, Chunlei. General conformal transformation method based on Schwarz-Christoffel approach. OPTICS EXPRESS[J]. 2011, 19(16): 15119-15126, http://ir.ioe.ac.cn/handle/181551/4982.[17] Shi, Lifang, Dong, Xiaochun, Deng, Qiling, Lu, Yueguang, Ye, Yutang, Du, Chunlei. Design and characterization of an axicon structured lens. OPTICAL ENGINEERING[J]. 2011, 50(6): http://ir.ioe.ac.cn/handle/181551/3450.[18] Zhang, Yukun, Du, Jinglei, Wei, Xingzhan, Shi, Lifang, Deng, Qiling, Dong, Xiaochun, Du, Chunlei. Resolution and stability analysis of localized surface plasmon lithography on the geometrical parameters of soft mold. APPLIED OPTICS[J]. 2011, 50(13): 1963-1967, http://ir.ioe.ac.cn/handle/181551/4983.[19] Yin, Shaoyun, Dong, Xiaochun, Wei, Xingzhan, Deng, Qiling, Shi, Lifang, Pan, Yiming, Du, Chunlei. Experimental study on polarization lens formed by asymmetrical metallic hole array. APPLIED OPTICS[J]. 2011, 50(31): G118-G122, http://www.irgrid.ac.cn/handle/1471x/1108204.[20] Xia, Liangping, Yin, Shaoyun, Gao, Hongtao, Deng, Qiling, Du, Chunlei. Sensitivity Enhancement for Surface Plasmon Resonance Imaging Biosensor by Utilizing Gold-Silver Bimetallic Film Configuration. PLASMONICS[J]. 2011, 6(2): 245-250, http://ir.ioe.ac.cn/handle/181551/3474.[21] Wang, Yifu, Dong, Xiaochun, Yuan, Guishan, Zheng, Guoxing, Du, Chunlei. Design method to enhance the transmittance of a structured lens based on nonperiodic sampling. OPTICAL ENGINEERING[J]. 2011, 50(1): http://ir.ioe.ac.cn/handle/181551/3441.[22] Wei, Xingzhan, Shi, Haofei, Dong, Xiaochun, Lu, Yueguang, Du, Chunlei. A high refractive index metamaterial at visible frequencies formed by stacked cut-wire plasmonic structures. APPLIED PHYSICS LETTERS[J]. 2010, 97(1): http://ir.ioe.ac.cn/handle/181551/3366.[23] Zhang, Maoguo, Du, Jinglei, Shi, Haofei, Yin, Shaoyun, Xia, Liangping, Jia, Baohua, Gu, Min, Du, Chunlei. Three-dimensional Nanoscale Far-field Focusing of Radially Polarized Light by Scattering the SPPs with an Annular Groove. OPTICS EXPRESS[J]. 2010, 18(14): 14664-14670, http://ir.ioe.ac.cn/handle/181551/4973.[24] Zhang, Yukun, Dong, Xiaochun, Du, Jinglei, Wei, Xingzhan, Shi, Lifang, Deng, Qiling, Du, Chunlei. Nanolithography method by using localized surface plasmon mask generated with polydimethylsiloxane soft mold on thin metal film. OPTICS LETTERS[J]. 2010, 35(13): 2143-2145, http://ir.ioe.ac.cn/handle/181551/3359.[25] Wei, Xingzhan, Shi, Haofei, Zheng, Guoxing, Dong, Xiaochun, Du, Chunlei. Modeling and experimental verification of optical materials formed by stacked nanostrips. OPTICS EXPRESS[J]. 2010, 18(14): 14842-14849, http://ir.ioe.ac.cn/handle/181551/4971.