Progress of Terahertz Devices Based on Graphene 被引量：2

Progress of Terahertz Devices Based on Graphene

下载PDF

导出

摘要 Graphene is a one-atom-thick planar sheet of sp2-hybridized orbital bonded honeycomb carbon crystal. Its gapless and linear energy spectra of electrons and holes lead to the unique carrier transport and optical properties, such as giant carrier mobility and broadband flat optical response. As a novel material, graphene has been regarded to be extremely suitable and competent for the development of terahertz （THz） optical devices. In this paper, the fundamental electronic and optic properties of graphene are described. Based on the energy band structure and light transmittance properties of graphene, many novel graphene based THz devices have been proposed, including modulator, generator, detector, and imaging device. This progress has been reviewed. Future research directions of the graphene devices for THz applications are also proposed. Graphene is a one-atom-thick planar sheet of sp2-hybridized orbital bonded honeycomb carbon crystal. Its gapless and linear energy spectra of electrons and holes lead to the unique carrier transport and optical properties, such as giant carrier mobility and broadband flat optical response. As a novel material, graphene has been regarded to be extremely suitable and competent for the development of terahertz （THz） optical devices. In this paper, the fundamental electronic and optic properties of graphene are described. Based on the energy band structure and light transmittance properties of graphene, many novel graphene based THz devices have been proposed, including modulator, generator, detector, and imaging device. This progress has been reviewed. Future research directions of the graphene devices for THz applications are also proposed.

作者 Mai-Xia Fu Yan Zhang

机构地区 Beijing Key Laboratory for Terahertz Spectroscopy and Imaging

出处《Journal of Electronic Science and Technology》 CAS 2013年第4期352-359,共8页 电子科技学刊（英文版）

基金 supported by the 973 Program of China under Grant No.2013CBA01702 the National Natural Science Foundation of China under Grant No.11204188,61205097,91233202,11374216,and 11174211 the National High Technology Research and Development Program of China under Grant No.2012AA101608-6 the Beijing Natural Science Foundation under Grant No.KZ201110028035 the Program for New Century Excellent Talents in University under Grant No.NCET-12-0607,and the CAEP THz Science and Technology Foundation

关键词 DETECTOR GENERATOR graphene imaging MODULATOR terahertz device. Detector, generator, graphene,imaging, modulator, terahertz device.

分类号 TN214 [电子电信—物理电子学]

引文网络
相关文献

参考文献34

1G. E Williams, "Filling the terahertz gap-high power sources and applications," Rep. Prog. Phys., vol. 69, no. 2, pp. 301-326, 2006.
2M. Tonouchi, "Cutting-edge terahertz technology," Nature Photon., 2007, doi: 10.1038/nphoton.2007.3.
3H. Hoshina, Y. Sasaki, A. Hayashi, C. Otani, and K. Kawase, "Noninvasive mail inspection system with terahertz radiation," Appl. Spectrosc., vol. 63, pp. 81-86, Apr. 2009.
4J. S. Melinger, S. S. Harsha, N. Laman, and D. Grischkowsky, "Temperature dependent characterization of terahertz vibrations of explosives and related threat materials," Opt. Express., vol. 18, pp. 27238-27250, Dec. 2010.
5S. Yoshida, K. Suizu, E. Kato, Y. Nakagomi, Y. Ogawa, and K. Kawase, "THz imaging techniques for nondestructive inspections," J. MoL Spectrosc., vol. 256, no. 7-8, pp. 146-151, 2009.
6M. Theuer, S. S. Harsha, D. Molter, G. Torosyan and R. Beigang, "Terahertz time-domain spectroscopy of gases, liquids, and solids," Chem Phys Chem., vol. 12, no. 15, pp. 2695-2705, 2011.
7H. T. Chert, J. F. O'Hara, A. K. Azad, A. J. Taylor, R. D. Averitt, D. B. Shrekenhamer, et al., "Experimental demonstration of frequency-agile terahertz metamaterials," Nat. Photonics, vol. 2, pp. 295-298, Apr. 2008.
8P. Weis, O. Paul, C. Imhof, R. Beigang, and M. Rahm, "Strongly birefringent metamaterials as negative index terahertz wave plates," AppL Phys. Lett., vol. 95, no. 17, pp. 171104-171104-3, 2009.
9J. Neu, B. K.rolla, O. Paul, B. Reinhard, R. Beigang, and M. Rahm, "Metamaterial-based gradient index lens with strong focusing in the THz frequency range," Opt. Express., 2010, doi: 10.1364/OE. 18.027748.
10K. S. Novoselov, A. IC Geim, S. V. Morozov, D. Jiang, Y. Zhang, S. V. Dubonos, et al., "Electric field effect in atomically thin carbon films," Science, vol. 306, no. 5696, pp. 666-669, 2004.

同被引文献17

1葛德彪,朱湘琴,杨利霞,郑奎松,魏兵,秦海俊.FDTD应用于各向异性介质及半空间散射问题[J].电波科学学报,2004,19(z1):41-44. 被引量：1
2William J. Wadsworth,Jonathan C. Knight,William H. Reeves,Philip St.J. Russell.Photonic Crystal Fibers[J].光学学报,2003,23(S1):11-12. 被引量：2
3Katsusuke Tajima.Recent Progress of Photonic Crystal Fibers[J].光学学报,2003,23(S1):29-30. 被引量：3
4赵小莹,周乐柱.不同参量的二维介质电磁带隙的反射及传输特性研究[J].北京大学学报（自然科学版）,2005,41(3):460-464. 被引量：4
5MALONEY J G, SMITH G S. The efficient modeling of thin material sheets in the finite-difference time-domain (FDTD)method[J]. IEEE transactions on antennas and propagation, 1992, 40(3) : 323-330.
6BOUZNIANAS G D, KANTARTZIS N V, ANTO- NOPOULOS C S, et al. Optimal modeling of infinite graphene sheets via a class of generalized FDTD schemes[J]. IEEE transactions on magnetics, 2012, 48(2) : 379-382.
7NAYYERI V, SOLEIMANI M, RAMAHI O M. Modeling graphene in the finite-diffierenee time- domain method using a surface boundary condition [J]. IEEE transactions on antennas and propagation, 2013, 61(8) : 4176-4182.
8PERES N M R, BLUDOV Y V. Enhancing the ab- sorption of graphene in the terahertz range[J]. IOP- science, 2013, 101(5): 58002.
9LIU J T, LIU N H, WANG L, et al. Gate-tunable nearly total absorption in graphene with resonant metal back reflector [J]. IOP science, 2013, 104(5): 57002.
10LOVAT G. Equivalent circuit for electromagnetic in- teraction and transmission through graphene sheets [J]. IEEE transactions on electromagnetic compati- bilit, 2012, 54(1). 101-109.

引证文献2

1杨利霞,李玲玲,朱婷,施丽娟.基于石墨烯一维太赫兹光子晶体电磁特性研究[J].电波科学学报,2016,31(2):262-268. 被引量：3
2丁润琪,侯尚林,雷景丽,王道斌,李晓晓,王慧琴,曹明华.太赫兹正六边形光子晶体光纤的液体传感（英文）[J].发光学报,2019,40(2):272-276. 被引量：2

二级引证文献5

1张茂婷,郑改革,吴红艳,饶伟锋.含石墨烯缺陷的一维光子晶体吸收特性研究[J].量子电子学报,2018,35(3):326-331. 被引量：4
2吴蓉,张璐瑶,严清博,刘振.用于液体传感的高双折射新型光子晶体光纤结构[J].应用光学,2020,41(3):637-644. 被引量：3
3顾有林,陆卫,方佳节,郑超,陈曦,王新宇,胡以华.人工制备红外消光材料及其消光性能研究进展(特约)[J].红外与激光工程,2020,49(7):1-14. 被引量：7
4薛兆康,国旗,刘善仁,潘学鹏,陈超,于永森.油气井下光纤光栅温度压力传感器[J].中国光学,2021,14(5):1224-1230. 被引量：5
5韩晓冰,张辉,梁冰洋,周远国.基于HIE-FDTD方法的太赫兹频段石墨烯吸收器的设计[J].电波科学学报,2022,37(1):106-112. 被引量：1

1姚振汉,蘧时胜.Identification of Equivalent Stiffness Parameters of Honeycomb Sandwich Shell Using Detailed Cell Structure Analysis[J].Tsinghua Science and Technology,1997,2(2):48-51.
2Ji-Ning Li,Wei Li,Sheng-Jiang Chang.Terahertz Metamaterial Modulator Based on Vanadium Dioxide[J].Journal of Electronic Science and Technology,2014,12(1):44-48.
3Li Zhi Zhang Ai-Xia Ma Juan Xue Ju-Kui.Energy band structure in optical of spin-1 condensates lattices[J].Chinese Physics B,2010,19(10):68-73.
4ZHANG Tong,CHENG Peng,LI Wenjuan,SUN Yujie,WANG Guang,ZHU Xiegang,HE Ke,WANG Lili,MA Xucun,CHEN Xi,WANG Yayu,LIU Ying,LIN Haiqing,JIA Jinfeng,XUE Qikun.Superconductivity in One-atomic-layer Metal Films[J].Bulletin of the Chinese Academy of Sciences,2011,25(4):301-303. 被引量：1
5刘诗涛,全知觉,王立.Carrier transport via V-shaped pits in InGaN/GaN MQW solar cells[J].Chinese Physics B,2017,26(3):558-563.
6王勇.RENISHAW仿形测头在SINUMERIK840C上的应用[J].制造技术与机床,2004(10):118-121.
7陈智,张雅鑫.Planar terahertz metamaterial with three-resonant frequencies[J].Chinese Physics B,2013,22(6):576-579. 被引量：2
8Cao, Shuyou, Shi, Bing, Liu, Xingnian, He, Jianyu.VECTORIAL COMPETENT VELOCITY FORMULATIONS ON ARBITRARY FACE S FOR NON-UNIFORM SEDIMENTS[J].Journal of Hydrodynamics,2000,12(3):29-33. 被引量：2
9Liu Xin, Li Kang, Kong Fanmin(School of Information Science and Engineering, Shandong University Jinan 250100, Shandong, P.R.China,Tel:86-531-8361608, E-mail:edwardlx@163.com).Simulation of Optical Devices Using Parallel FDTD Method[J].光学学报,2003,23(S1):307-308.
10张瑞,王志斌,李晓,陈友华,王耀利,杨强.单弹光调制傅里叶偏振光谱测量研究[J].应用光学,2014,35(1):95-99. 被引量：1

Journal of Electronic Science and Technology

2013年第4期

浏览历史

内容加载中请稍等...

Progress of Terahertz Devices Based on Graphene 被引量：2

参考文献34

同被引文献17

引证文献2

二级引证文献5

相关作者

相关机构

相关主题

浏览历史