Oscillation effect in frequency domain current from a photoconductive antenna via double-probe-pulse terahertz detection technique 被引量：1

Oscillation effect in frequency domain current from a photoconductive antenna via double-probe-pulse terahertz detection technique

原文传递

导出

摘要 Via constructing a special terahertz time domain spectroscopy （THz-TDS） system in which two femtosecond （fs） laser pulses were used as probe pulses to excite a photoconductive （PC） THz detector, the time behavior of the current from the detector was measured.The corresponding theoretical analysis was performed by a well-known equivalent-circuit model. When the time domain current was transformed to frequency domain, an oscillation effect was observed. The oscillation frequency was decided by the time delay between the two probe pulses. The number of the extrema in the frequency domain current curve was proportion to the pulse interval in 0.1 -2 THz. A method to measure the interval offs laser pulses was proposed. It is important for applications of fs laser pulses or train. Via constructing a special terahertz time domain spectroscopy （THz-TDS） system in which two femtosecond （fs） laser pulses were used as probe pulses to excite a photoconductive （PC） THz detector, the time behavior of the current from the detector was measured.The corresponding theoretical analysis was performed by a well-known equivalent-circuit model. When the time domain current was transformed to frequency domain, an oscillation effect was observed. The oscillation frequency was decided by the time delay between the two probe pulses. The number of the extrema in the frequency domain current curve was proportion to the pulse interval in 0.1 -2 THz. A method to measure the interval offs laser pulses was proposed. It is important for applications of fs laser pulses or train.

作者 Qi JIN Jinsong LIU Kejia WANG Zhengang YANG Shenglie WANG Kefei YE

机构地区 Wuhan National Laboratory for Optoelectronics

出处《Frontiers of Optoelectronics》 CSCD 2015年第1期104-109,共6页 光电子前沿（英文版）

关键词 terahertz （THz） PHOTOCONDUCTIVITY frequency oscillation terahertz （THz）, photoconductivity, frequency oscillation

分类号 TN24 [电子电信—物理电子学] TN752 [电子电信—电路与系统]

引文网络
相关文献

参考文献12

1Pedersen J E, Lyssenko V G, Hvam J M, Jepsen P U, Keiding S R, Sorensen C B, Lindelof P E. Ultrafast local field dynamics in photoconductive THz antennas. Applied Physics Letters, 1993, 62 (11): 1265 -1267.
2Jacobsen R H, Birkelund K, Hoist T, Jepsen P U, Keiding S R. Interpretation of photocurrent correlation measurements used for ultrafast photoconductive switch characterization. Journal of Applied Physics, 1996, 79(5): 2649 -2657.
3Jepsen P U, Jacobsen R H, Keiding S R. Generation and detection of terahertz pulses from biased semiconductor antennas. Journal of the Optical Society of America B, Optical Physics, 1996, 13( 11 ): 2424- 2436.
4Yano R, Gotoh H, Hirayama Y, Miyashita S. Systematic pump- probe terahenz wave emission spectroscopy of a photoconductive antenna fabricated on low-temperature grown GaAs. Journal of Applied Physics, 2004, 96(7): 3635- 3638.
5Loata G C. Investigation of low-temperature-grown GaAs photo- conductive antennae for continuous-wave and pulsed terahertz generation. Dissertation for the Doctoral Degree. Frankfut am Main: Goethe-University, 2007.
6Loata G C, Lrffler T, Roskos H G. Evidence for long-living charge carriers in electrically biased low-temperature-grown GaAs photo- conductive switches. Applied Physics Letters, 2007, 90(5): 052101 - 1 052101-3.
7Loata G C, Thomson M D, Lrffier T, Roskos H G. Radiation field screening in photoconductive antennae studied via pulsed terahertz emission spectroscopy. Applied Physics Letters, 2007, 9[(23): 232506-1 232506-3.
8Siebert K J, Lisauskas A, Lrffler T, Roskos H G. Field screening in low-temperature-grown GaAs photoconductive antennas. Japanese Journal of Applied Physics, 2004, 43(3R): 1038- 1043.
9Darrow J T, Zhang X, Auston D H, Morse J D. Saturation properties of large-aperture photoconducting antennas. IEEE Journal of Quantum Electronics, 1992, 28(6): 1607 -1616.
10Liu J, Zou S, Yang Z, Wang K, Ye K. Wave shape recovery for terahertz pulse field detection via photoconductive antenna. Optics Letters, 2013, 38(13): 2268 -2270.

同被引文献7

1张存林,牧凯军.太赫兹波谱与成像[J].激光与光电子学进展,2010,47(2):1-14. 被引量：69
2罗兴平,张大勇,王燕,张全,樊海涛.MDT单压力点确定油/气/水界面方法[J].测井技术,2011,35(2):180-182. 被引量：9
3金武军,李军.原油乳状液的太赫兹表征与评价[J].中国科学：物理学、力学、天文学,2015,45(8):40-50. 被引量：2
4ZHAN HongLei,SUN ShiNing,ZHAO Kun,LENG WenXiu,BAO RiMa,XIAO LiZhi,ZHANG ZhenWei.Less than 6 GHz resolution THz spectroscopy of water vapor[J].Science China(Technological Sciences),2015,58(12):2104-2109. 被引量：10
5熊兆贤,黄金保,薛昊,邱虹,宋春晓.太赫兹时域光谱系统检测MCT陶瓷太赫兹性能[J].太赫兹科学与电子信息学报,2014,12(5):663-666. 被引量：6
6王波,张岩.太赫兹超材料和超表面器件的研发与应用[J].太赫兹科学与电子信息学报,2015,13(1):1-12 18. 被引量：13
7詹洪磊,王玉霞,王雪松,赵昆.煤炭标准物质的太赫兹光谱聚类分析[J].太赫兹科学与电子信息学报,2016,14(1):26-30. 被引量：9

引证文献1

1王丹丹,詹洪磊,苗昕扬,姜晨,宋艳,管丽梅,赵昆.油气水界面的太赫兹频谱[J].太赫兹科学与电子信息学报,2016,14(6). 被引量：1

二级引证文献1

1李超,秦凡凯,孟昭晖,陈儒,杨颀,杨义勤,苗昕扬,赵昆,詹洪磊.结合有效介质理论的乳状液太赫兹光谱分析[J].大学物理,2021,40(4):27-31.

1王慧.双探头激光发散角的测量方法[J].科技创新与应用,2016,6(14):39-40.
2汤跃明,任鸣鸣.双探头人体红外探测器[J].河南师范大学学报（自然科学版）,1994,22(2):96-99.
3施卫,张真真,侯磊.Electrical Field Distribution in Terahertz SI-GaAs Photoconductive Antennas[J].Chinese Physics Letters,2010,27(8):169-171.
4IVi@nncorp：MC-392双探头LED贴片机[J].现代表面贴装资讯,2013(2):7-7.
5何骥.锑化铟双探头探测器及液氦实验杜瓦的研制[J].低温工程,1990(4):32-39.
6慕建伟,姚军,吕颖琦.基于双探头的新型液晶显示器响应时间测量方法的研究[J].光电子．激光,2008,19(2):218-220. 被引量：3
7汪映海,胡成生.双光子激光的时间行为[J].激光技术,1992,16(6):365-368.
8傅盘铭,俞祖和,米辛,姜谦.瑞利型非简并四波混频:一种研究超快过程的新方法[J].物理,2002,31(10):621-623.
9王慧琴,欧阳红,韩道福,王一凡.Fabricating scheme and optical properties of a flexible semiconductor micro-laser[J].Optoelectronics Letters,2011,7(3):178-181.
10李良成,李凯扬,秦钊.新型近红外脑血氧监测设备的研制[J].激光与红外,2006,36(8):661-664. 被引量：13

Frontiers of Optoelectronics

2015年第1期

浏览历史

内容加载中请稍等...

Oscillation effect in frequency domain current from a photoconductive antenna via double-probe-pulse terahertz detection technique 被引量：1

参考文献12

同被引文献7

引证文献1

二级引证文献1

相关作者

相关机构

相关主题

浏览历史