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A GaAs photoconductive antenna is one of the important radiation sources of terahertz electromagnetic waves. Antenna arrays can increase the radiation intensity of terahertz waves. Therefore, photoconductive antennas and arrays have attracted much attention for a long time. In this study, CST Microwave Studio is used to conduct a simulation calculation of the characteristics of a photoconductive antenna array radiating terahertz electromagnetic waves. Using the current transient model, the pulsed photocurrents generated when the laser is incident on the GaAs photoconductive antenna are calculated. With the pulsed photocurrents serving as an excitation source, a simulation calculation of the radiation performance of photoconductive antenna is conducted, and the effects of antenna structure and substrate material on the radiation of terahertz waves are analyzed. Based on this, the far-field radiation of terahertz wave radiated by the GaAs photoconductive antenna array is calculated. The simulation results show that the photoconductive antenna array radiates terahertz waves with stronger directivity. The width of main lobe is reduced, and its far-field radiation conforms to the multiple relationships of electric field superposition. A 1 × 2 GaAs photoconductive antenna array is developed, and the experimental results are consistent with the simulation conclusions, thereby laying a theoretical and experimental basis for fabricating the multielement terahertz photoconductive antenna arrays.
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Keywords:
- terahertz /
- electromagnetic wave /
- photoconductive antenna /
- antenna array
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[22] Benicewicz P K, Roberts J P, Taylor A J 1994 J. Opt. Soc. Am. B 11 2533Google Scholar
[23] Hattori T, Tukamoto K, Nakatsuka H 2001 Jpn. J. Appl. Phys. 40 4907Google Scholar
[24] Tani M, Matsuura S, Sakai K, Nakashima S 1997 Appl. Optics 36 7853Google Scholar
[25] Liu H, Ji W L, Shi W 2008 PIERS Online 4 386Google Scholar
[26] Yan Z J, Shi W, Hou L, Xu M, Yang L, Dong C G, Li S T 2017 Mater. Res. Express 4 015304Google Scholar
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[1] Ferguson B, Zhang X C 2002 Nat. Mater. 1 26Google Scholar
[2] Yen T J, Padilla W J, Fang N, Vier D C, Smith D R, Pendry J B, Basov D N, Zhang X J 2004 Science 303 1494Google Scholar
[3] Wang K L, Mittleman D M 2004 Nature 432 376Google Scholar
[4] Chen H T, Padilla W J, Zide J M O, Gossard A C, Taylor A J, Averitt R D 2006 Nature 444 597Google Scholar
[5] Tonouchi M 2007 Nat. Photonics 1 97Google Scholar
[6] Huang K C, Wang Z C 2011 IEEE Microw. Mag. 12 108Google Scholar
[7] Oh S J, Huh Y M, Haam S, Suh J S, Son J H 2012 37th International Conference on Infrared, Millimeter, and Terahertz Waves Wollongong, Australia, September 23−28, 2012 p1
[8] Kemp M C, Taday P F, Cole B E, Cluff J A, Fitzgerald A J, Tribe W R 2003 Terahertz for Millitary and Security Applications Orlando, USA, July 29, 2003 p44
[9] Nagel M, Bolivar P H, Burcherseifer M, Bosserhoff H K, Buttner R 2002 Appl. Phys. Lett. 80 154Google Scholar
[10] Mickan S, Abbott D, Munch J, Zhang X C, Doorn T 2000 Microelectron. J. 31 503Google Scholar
[11] He Y J, Chen Y L, Zhang L, Wong S W, Chen Z N 2020 China Commun. 17 124Google Scholar
[12] Awad M, Nagel M, Kurz H, Herfort J, Ploog K 2007 Appl. Phys. Lett. 91 181124Google Scholar
[13] Tiedje H F, Saeedkia D, Nagel M, Haugen H K 2010 IEEE T. Microw. Theory 58 2040Google Scholar
[14] Yang X X, Vorobiev A, Yang J, Jeppson K, Stake J 2020 IEEE T. THz. Sci. Techn. 10 554Google Scholar
[15] Knotts M E, Denison D R 2006 Quantum Electronics and Laser Science Conference Long Beach, USA, May 21−26, 2006 p24
[16] Berenger J P 1994 J. Comput. Phys. 114 185Google Scholar
[17] Berenger J P 1996 J. Comput. Phys. 127 363Google Scholar
[18] Berenger J P 1996 IEEE T. Antenn. Propag. 44 110Google Scholar
[19] Weiland T 1996 Int. J. Numer. Model. El. 9 295
[20] Weiland T, Timm M, Munteanu I 2008 IEEE Microw. Mag. 9 62Google Scholar
[21] Darrow J T, Zhang X C, Auston D H, Morse J D 1992 IEEE J. Quantum Elect. 28 1607Google Scholar
[22] Benicewicz P K, Roberts J P, Taylor A J 1994 J. Opt. Soc. Am. B 11 2533Google Scholar
[23] Hattori T, Tukamoto K, Nakatsuka H 2001 Jpn. J. Appl. Phys. 40 4907Google Scholar
[24] Tani M, Matsuura S, Sakai K, Nakashima S 1997 Appl. Optics 36 7853Google Scholar
[25] Liu H, Ji W L, Shi W 2008 PIERS Online 4 386Google Scholar
[26] Yan Z J, Shi W, Hou L, Xu M, Yang L, Dong C G, Li S T 2017 Mater. Res. Express 4 015304Google Scholar
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