[1] SIEGEL P H. Terahertz technology[J]. IEEE T. Microw. Theory,2002,50(3):910-928.
[2] ZHANG X CH. Materials for Terahertz science and technology[J]. Physics,2003,32(5):287-293.
[3] SHERWIN M S,SCHMUTTENMAER C A,BUCKSBAUM P H. Opportunities in Terahertz(THz) Science //Report of a DOE-NSF-NIH Workshop on Opportunities in THz Science,Feb.12-14 2004,Arlington,USA,2004.
[4] 刘盛刚. THz科学技术的新发展[J]. 中国基础科学,2006,1:7-12. LIU SH G. Recent development of terahertz science and technology[J]. China Basic Sci.,2006,1:7-12.(in Chinese)
[5] 姚建铨. 太赫兹技术及其应用[J]. 重庆邮电大学学报(自然科学版),2010,22(6):703-707. YAO J Q. Introduction of THz-wave and its applications[J]. J. Chongqing University Posts and Telecommunications(Natural Science Edition),22(6):703-707.(in Chinese)
[6] SHUMYATSKY P,ROBERT R. Terahertz sources[J]. J. Biomed. Opt.,2011,16(3):033001.
[7] MUELLER E R. Terahertz radiation sources for imaging and sensing applications[J]. Photonics Spectra,2006,40:60-69.
[8] BAE J,NOZOKIDO T,SHIRAI H,et al.. An EMQ-switched CO2 laser as a pump source for a far-infrared laser with a high peak power and a high repetition[J]. IEEE J. Quantum Elect.,1989,25(7):1591-1594.
[9] 冉勇,秦家银. 小型光泵腔式NH3分子亚毫米波激光器的实验研究[J]. 光电子·激光,1999,12:495-497. RAN Y,QIN J Y. Experimental study of miniature optically pumped cavity NH3 submillimeter wave laser[J]. J. Optoelectronic·Laser,1999,12:495-497.(in Chinese)
[10] 冉勇,秦家银,李太全,等. 光泵腔式远红外激光器的工作参数研究[J]. 激光与红外,2002,32:245-247. RAN Y,QIN J Y,LI T Q,et al.. Study on operating parameter of optically pumped cavity NH3 far-infrared laser[J]. Laser & Infrared,2002,32:245-247.(in Chinese)
[11] 纠智先. 可调谐TEA-CO2激光泵浦的脉冲THz激光器性能研究 . 武汉:华中科技大学,2010. JIU ZH X. Performance studies on pulsed THz laser pumped by tunable TEA CO2 laser . Wuhan:Huazhong Universith of Science & Technology,2010.(in Chinese)
[12] 何志红. 光泵重水气体分子产生THz激光辐射技术的研究 . 天津:天津大学,2007. HE ZH H. Study of THz radiation generated by optically-pumped D2O gas molecules . Tianjin:Tianjin University,2007.(in Chinese)
[13] HE ZH H,YAO J Q,REN X,et al.. Experimental and theoretical research on a compact superradiant optically pumped D2O gas Terahertz laser[J]. J. Optoelectronics. Laser,2008,19(1):35-37.
[14] 田兆硕,王静,费非,等. 光抽运全金属太赫兹激光器研究[J]. 中国激光,2010,37(9):2323-2327. TIAN ZH SH,WANG J,FEI F,et al.. Study of optically pumped all-metal terahertz laser[J]. Chinese J. Lasers,2010,37(9):2323-2327.(in Chinese)
[15] 张怀武. 我国太赫兹基础研究[J]. 中国基础科学,2008,1:15-20. ZHANG H W. Terahertz basic research in China[J]. China Basic Science,2008,1:15-20.
[16] MUELLER E R,HENSCHKE R,ROBOTHAM W E Jr,et al.. Terahertz local oscillator for the microwave limb sounder on the aura satellite[J]. Appl. Opt.,2007,46:4907-4915.
[17] HAMSTER H,SULLIVAN A,GORDON S,et al.. Subpicosecond, electromagnetic pulses from intense laser-plasma interaction[J]. Phys. Rev. Lett.,1993,71:2725-2728.
[18] XIE X,DAI J M,ZHANG X C. Coherent control of THz wave generation in ambient air[J]. Phys. Rev. Lett.,2006,96:075005.
[19] KIM K Y,TAYLOR A J,GLOWNIA J H,et al.. Coherent control of terahertz supercontinuum generation in ultrafast laser gas interactions[J]. Nature Photonics,2008,2:605-609.
[20] WANG T J,DAIGLE J F,CHEN Y,et al.. High energy THz generation from meter-long two-color filaments in air[J]. Laser Phys. Lett.,2010,7(7):517-521.
[21] WANG T J,YUAN S,CHEN Y P,et al.. Toward remote high energy terahertz generation[J]. Appl. Phys. Lett.,2010,97:111108.
[22] AUSTON D H. Picosecond optoelectronic switching and gating in silicon[J]. Appl. Phys. Lett.,1975,6(3):101-103.
[23] LEE CH H. Picosecond optoelectronic switching in GaAs[J]. Appl. Phys. Lett.,1977,30(2):84-86.
[24] 赵尚弘,陈国夫,赵卫,等. THz射线产生技术及应用最新进展[J]. 激光技术,2000,24(6):352-353. ZHAO SH H,CHEN G F,ZHAO W,et al.. Generation and recent advances in applications of terahertz ray[J]. Laser Technology,2000,24(6):352-353.(in Chinese)
[25] 施卫,张显斌,贾婉丽,等. 用飞秒激光触发GaAs光电导体产生THz电磁波的研究[J]. 半导体学报,2004,25(12):1735-1738. SHI W,ZHANG X B,JIA W L,et al.. Investigation on terahertz generation with GaAs photoconductor triggered by femo-second laser pulse[J]. Chinese J. Semiconductors,2004,25(12):1735-1738.(in Chinese)
[26] MADEO J,JUKAM N,OUSTINOV D,et al.. Frequency tunable terahertz interdigitated photoconductive antennas[J]. Electronics Lett.,2010,46(9):611-613.
[27] Photoconductive anterna for THz applications .(2010-06-07) http://greyhawkoptics.com/images/PCA_web.pdf?osCsid=89abc4616d9f05846db27440ac48e44c.
[28] FULOP J A,PALFALV I L,ALMASI G,et al.. Design of high-energy terahertz sources based on optical rectification[J]. Opt. Express,2010,18:12311-12327.
[29] AHN J,EFIMOV A V,AVERITT R D,et al.. Terahertz waveform synthesis via optical Rectification of shaped ultra-fast laser pulses[J]. Opt. Express,2003,11(20):2486-2496.
[30] YEH K L,HOFFMANN M C,HEBLING J,et al.. Generation of 10 μJ ultrashort terahertz pulses by optical rectification[J]. Appl. Phys. Lett.,2007,90(17):171-121.
[31] STEPANOV A G,BONACINA L,CHEKALIN S V,et al.. Generation of 30 μJ single-cycle terahertz pulses at 100 Hz repetition rate by optical rectification[J]. Opt. Lett.,2008,33(21):2497-2499.
[32] NEGEL J P,HEGENBARTH R,STEINMANN A,et al.. Compact and cost-effective scheme for THz generation via optical rectification in GaP and GaAs using novel fs laser oscillators[J]. Appl. Phys. B, 2011,103:45-50.
[33] ZERNIKE Jr F,BERMAN P R. Generation of far-infrared as a difference frequency[J]. Phys. Rev. Lett.,1965,15(26):999-1002.
[34] FARIES D W,RICHARDS P L,SHEN Y R. Tunable far-infrared radiation generated from the difference frequency between two ruby lasers[J]. Phys. Rev.,1969,180(2):363-365.
[35] KAWASE K,MIZUNO M,SOHMA S,et al.. Difference-frequency terahertz-wave generation from 4-dimethylaminolium-tosylate by use of an electronically tuned Ti∶sapphire laser[J]. Opt. Lett.,1999,24:1065-1067.
[36] KAWASE K,SHIKATA J I,ITO H. Terahertz wave parametric source[J]. Appl. Phys. Lett.,2001,34:1-14.
[37] TOCHITSKY S Y,RALPH J E,SUNG C,et al.. Generation of megawatt-power terahertz pulses by noncollinear difference-frequency mixing in GaAs[J]. Appl. Phys.,2005,98:026101.
[38] DING Y J,MU X D. Power scaling of widely-tunable monochromatic and quasi-single-cycle THz sources //Infrared Millimeter Waves and 14th International Conference on Teraherz Electronic,2006 IRMMW,Sept 28-22 2006,Shanghai,China,2006.
[39] JIANG Y,DING Y J,ZoTOVA I B. Power scaling of widely-tunable monochromatic THz pulses based on difference-frequency generation in a pair of stacked GaP plates //Laser and Electro-optics(CLEO) and Quantum Electronics and Laser Science Conference(QELS),2010 Conference on,May 16-21 2010,San Jose,USA,2010.
[40] TANABE T,SUTO K,NISHIZAWA J,et al.. Tunable terahertz wave generation in the 3- to 7-THz region from GaP[J]. Appl. Phys. Lett.,2003,83:237-239.
[41] MIYAMOTO K,YAMASHITA T,NAWAHARAL A,et al.. Frequency-agile coherent tunable THz-wave generation from 1.5 to 60 THz using Galvano controlled KTP-OPO //Infrared Millimeter Waves and 14th International Conference on Teraherz Electronic,2006 IRMMW,Sept 28-22 2006,Shanghai,China,2006.
[42] VODOPYANOV K L,FEJER M M,YU X,et al.. Terahertz wave generation in quasi-phase-matched GaAs[J]. Appl. Phys. Lett.,2006,89:141119.
[43] VODOPYANOV K L. Optical THz-wave generation with periodically-inverted GaAs[J]. Laser & Phot. Rev.,2008,2:11-25.
[44] 路洋. 基于非线性晶体利用光学差频产生THz波辐射的研究 . 天津:天津大学,2006. LU Y. Study of THz radiation generated via optical difference frequency generation based on nonlinear crystal . Tianjin:Tianjin University,2006.(in Chinese)
[45] 孙博. 基于差频技术及光学参量方法产生可调谐THz波的研究 . 天津:天津大学,2007. SUN B. Study of tunable THz-wave generation via difference frequency generation and optical parametricprocess . Tianjin:Tianjin University,2007.(in Chinese)
[46] 耿优福. 太赫兹波的差频产生及低损耗传输波导的研究 . 天津:天津大学,2009. GENG Y F. Study on difference-freqency generation of terahertz waves and low loss waveguides for terahertz yransmission . Tianjin:Tianjin University,2009.(in Chinese)
[47] KAWASE K,SHIKATA J-I,ITO H. Terahertz wave parametric source[J]. Phys. D,Appl. Phys.,2002,35:R1-R14.
[48] MINAMIDE H,IKARI T,ITO H. Frequency agile terahertz wave parametric oscillator in a ring cavity configuration[J]. Rev. Scientific Instruments,2009,80(12):123104.
[49] MALCOLM G. New laser sources benefit terahertz and mid-infrared remote sensing[J]. SPIE Newsroom,2007,10:842.
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