dc.relation.reference | 1.1. Chattopadhyay G, Schlecht E, Ward J S, Gill J J, Javadi H H S, Maiwald F and Mehdi I 2004 IEEE Trans. Microw. Theory Tech. 52 1538–47
1.2. Siegel, P. H., (2002) “Terahertz Technology”, IEEE Trans Microwave Theory & Techniques, 50, 910-928.
1.3. Mittleman, D., (2003) Sensing with Terahertz Radiation. Springer: New York.
1.4. Woodlard, D.L.; William, R.L., (2003) Terahertz Sensing Technology. World Scientific Publishing: Berlin; London.
1.5. Ferguson, B.; Zhang, X.-C., (2002) "Materials for terahertz science and technology," Nature materials 1, 26-33.
1.6. Zhang, X.-C., (2005) “Pulsed systems, electro-optic detection, and applications” Int. School of Solid State Physics, 36th Workshop: Physics and Technology of THz Photonics (Erice, Italy, 20–26 July)
1.7. Mueller, E., (2005) “Coherent cw THz transceivers” Int. School of Solid State Physics, 36th Workshop: Physics and Technology of THz Photonics (Erice, Italy, 20–26 July)
1.8. Hadjiloucas, S.; Karatzas, L. S.; and Bowen, J. W., (1999) “Measurement of leaf water content using terahertz radiation” IEEE Trans. Microw. Theory Tech. 47, 142–149.
1.9. Chamberlain, J. M., (2004) “Where optics meets electronics: recent progress in decreasing the terahertz gap”, Phil. Trans. R. Soc. Lond. A, 362, 199-213.
1.10. Auston, D. H., (1975) “Picosecond optoelectronic switching and gating in silicon”, Appl Phys. Lett. 26, 101-103.
1.11. Smith, P. R.; Auston, D. H.; and Nuss, M. C.; (1988) “Subpicosecond photoconductive dipole antennas”, IEEE J. Quantum Electron, 24, 255-260.
1.12. Jepsen, P. Uhd; Jacobsen R. H.; Keiding, S. R.; (1996) “Generation and detection of terahertz pulses from biased semiconductor antennas”, J. Opt. Soc. Am. B, 13, 2424-2436.
1.13. Brown, E. R.; Smith, F. W.; and McIntosh, K. A.; (1993) “Coherent millimetre wave generation by heterodyne conversion in low-temperature-grown GaAs photoconductors”, J. Appl. Phys., 73, 1480-1484.
1.14. Brown, E. R.; McIntosh, K. A.; Nichols, K. B., and Dennis, C. L.; (1995) “Photomixing up to 3.8 THz in lowtemperature-grown GaAs”, Appl. Phys. Lett., 66, 285-287.
1.15. Verghese, S.; K. McIntosh; Calawa, A. S.; Dinatale, W. F.; Duerr, E. K.; and Molvar, K. A., (1998) “Generation and detection of coherent terahertz waves using two photomixers”, Appl. Phys. Lett., 73, 3824-3826.
1.16. Gregory,I. S.; Tribe, W. R.; Cole, B. E.; Baker,C.; Evans, M. J.; Bradley, I. V.; Linfield, E. H.; Davies,A. G.; and Missous, M., (2004) “Phase sensitive continuous-wave THz imaging using diode lasers”, Electron. Lett., 40, 143-145.
1.17. Gregory, I. S.; Tribe, W. R.; Cole, B. E.; Evans, M. J.; Linfield, E. H.; Davies, A. G.; and Missous, M.; (2004) “Resonant dipole antennas for continuous-wave terahertz photomixers”, Appl. Phys. Lett., 85, 1622-1624.
1.18. Davies, A. G.; Linfield, E. H.; and Johnston, M. B.; (2002) “The development of terahertz sources and their applications”, Phys. Med. Biol., 47, 3679-3689.
1.19. Köhler, R.; Tredicucci, A.; Beltram, F.; Beere, H. E.; Linfield, E. H.; Davies, A. G.; Ritchie, D. A.; Iotti, R. C.; and Rossi, F., (2002) “Terahertz semiconductor-heterostructure laser”, Nature, 417, 156-159.
1.20. Kumar, S.; Williams, B. S.; Hu, Q.; and Reno, J. L., (2006) “1.9-THz quantum-cascade lasers with one-well Injector”, Appl. Phys. Lett., 88, 121123.
1.21. Staprans, A.; McCune, E.; and Ruetz, J., (1973) “High power linear beam tubes”, Proc. IEEE, 61, 299-330.
1.22. Carlstrom, J. E.; Plambeck, R.L.; Thornton, D.D., (1985) “A Continuously Tunable 65--15-GHz Gunn Oscillator,” IEEE Trans. Microwave Theory and Tech., 33, 610-619.
1.23. Hesler, J.; Porterfield, D.; Bishop, W.; Crowe, T.; Baryshev, A.; Hesper R.; and Baselmans, J., (2005) "Development and Characterization of an Easy-to-Use THz Source", Proc. 16th Intl. Symposium on Space Terahertz Technology, Goteborg, Sweden.
1.24. Crowe, T.W.; Bishop, W. L.; Porterfield, D. W.; Hesler, J. L.; Weikle, R. M., (2005) “Opening the terahertz window with integrated diode circuits,” IEEE J. Solid States Circuits, 40, 2104- 2110.
1.25. Kawase, K.; Sato, M.; Taniuchi, T.; and Ito, H., (1996) “Coherent tunable terahertz-wave generation from LiNbO3 with monolithic grating coupler”, Appl. Phys. Lett., 68, 2483-2485.
1.26. Kawase, K.; Shikata, J.; and Ito, H., (2001) “Terahertz wave parametric source”, Journal of Physics D, 34, R1-R14.
2.1. Kawase, K; Ogawa, Y; Watanabe, Y, (2003) "Nondestructive terahertz imaging of illicit drugs using spectral fingerprints," Opt. Express 11 2549.
2.2. Watanabe, Y; Kawase, K; and Ikari, T, (2003) “Component spatial pattern anaysis of chemicals using terahertz spectral imaging”, Appl. Phys. Lett., 83, 800-802.
2.3. Chan, T.L.J.; Bjarnason, J.E.; Lee, A.W.M.; Celis, M.A.; and Brown, E.R., (2004) “Attenuation contract between biomolecular and inorganic materials at terahertz frequencies”, Appl. Phys. Lett., 85, 2523.
2.4. Wallace, V. P.; Fitzgerald, A. J.; Shankar, S.; Flanagan, N.; Pye, R. J.; Cluff, J.; and Arnone, D. D., (2004) “Terahertz pulsed imaging of basal cell carcinoma ex vivo and in vivo,” B. J. Derm. 151 424–432.
2.5. Fitzgerald, A. J.; Wallace, V. P.; Jimenez-Linan, M.; Bobrow, L; Pye, R. J.; Purushotham, A. D.; and Arnone, D. D., (2006) “Terahertz pulsed imaging of human breast tumors,” Radiology 239 533–540.
2.6. Pickwell, E.; Cole, B. E.; Fitzgerald. A. J.; Pepper, M.; and Wallace, V. P., (2004) “In vivo study of human skin using pulsed terahertz radiation,” Phys. Med. Biol. 49 1595–1607.
2.7. Beard, M. C.; Turner, G. M.; and Schmuttenmaer, C. A., (2002) Liquid Dynamics: Experiment, Simulation and Theory, Oxford University Press: Oxford, 44–57.
2.8. Smith, P. R.; Auston, D. H.; and Nuss, M. C.; (1988) “Subpicosecond photoconductive dipole antennas”, IEEE J. Quantum Electron, 24, 255-260.
2.9. Fattinger, C.; and Grischkowsky, D., (1989) “Terahertz beams,” Appl. Phys. Lett., 54, 490–492.
2.10. Hu, B. B.; and Nuss, M. C., (1995) “Imaging with terahertz waves,” Opt. Lett. 20, 1716–1719.
2.11. Chen, Y.; Liu, H.; Deng, Y.; Veksler, D., Shur, M.; and Zhang, X.-C., (2004) “Spectroscopic characterization of explosives in the far infrared region” SPIE Defense and Security Symp. #5411-2.
2.12. Ferguson, B. S.; Liu, H.; Hay, S.; Findlay, D.; Zhang, X.-C.; and Abbott, D.’ (2004) “In vitro osteosarcoma biosensing using THz time domain spectroscopy” Proc. SPIE—Int. Soc. Opt. Eng.5275, 304.
2.13. McClatchey, K.; Reiten, M. T.; and Cheville, R. A., (2001) “Time resolved synthetic aperture terahertz impulse imaging” Appl. Phys. Lett. 79, 4485–4487.
2.14. Pearce, J.; and Mittleman, D., (2001) “Propagation of single-cycle terahertz pulses in random media” Opt. Lett. 26, 2002.
2.15. Cheville, R. A.; McGowan, R.Wand.; Grischkowsky, D., (1998) “Time resolved measurements which isolate the mechanisms responsible for terahertz glory scattering from dielectric spheres” Phys. Rev. Lett. 80, 269.
2.16. Hartwick, T., (1977) “Far infrared imaging techniques for law enforcement applications” SPIE Opt. Secur. LawEnforcement 108, 139.
2.17. Siebert, K.; Loffler, T.; Quast, H.; Thomson, M.; Bauer, T.; Leonhardt, R.; Czasch, S.; and Roskos, H. G., (2002) “All-optoelectronic continuous wave THz imaging for biomedical applications” Phys. Med. Biol. 47, 3743.
2.18. Darmo, J.; Tamosiunas. V.; Fasching. G.; Kroll, J.; Unterrainer, K.; Beck, M.; Giovannini, M.; Faist, J.; Kremser, C.; and Debbage, P., (2004) “Imaging with a terahertz quantum cascade laser“ Opt. Express 12, 1879.
2.19. Karpowicz, N.; Zhong, H.; Xu, J.; Lin, K.-I.; Hwang, J.-S.; and Zhang, X.-C., (2005) "Comparison between pulsed terahertz time-domain imaging and continuous wave terahertz imaging," Semicond. Sci. Technol. 20, 239-299.
2.20. Dobroiu, A.; Yamashita, M.; Ohshima, Y. N.; Morita, Y.; Otani, C.; and Kawase, K., (2004) “Terahertz imaging system based on a backward-wave oscillator” Appl. Opt. 43, 5637.
2.21. Kawase, K.; Shikata, J.; and Ito, H., (2001) “Terahertz wave parametric source”, Journal of Physics D, 34, R1-R14.
2.22. Ostmann, T. K.; Knobloch, A.; Koch, M.; Hoffmann, S.; Breede, M.; Hofmann, M.; Hein, G.; Pierz, K.; Sperling, M.; and Donhuijsen, K., (2001) “Continuous wave THz imaging,” Electronics Lett., 37, 1461 –1463.
2.23. Gregory, I. S.; Tribe, W.R.; Cole, B.E.; Baker, C.; Evans, M.J.; Bradley, I.V.; Linfield, E.H.; Davies, A.G.; and Missous, M., (2004) “Phase sensitive continuous wave THz imaging using diode lasers,” Electronics Lett., 40, 143-144.
2.24. Nahata, A.; Yardley, J. T.; and Heinz, T.F., (2002) “Two-dimensional imaging of continuous-wave terahertz radiation using electro-optic detection,” Appl. Phys. Lett., 81, 963-965.
2.25. Duffy, S. M.; Verghese, S.; McIntosh, K. A.; Jackson, A.; Gossard, A. C.; and Matsuura, S., (2001) “Accurate modeling of dual dipole and slot elements used with photomixers for coherent terahertz output power,” IEEE Trans. Microwave Theory Tech., 49, 1032-1038.
2.26. Gregory,I. S.; Tribe, W. R.; Cole, B. E.; Baker,C.; Evans, M. J.; Bradley, I. V.; Linfield, E. H.; Davies,A. G.; and Missous, M., (2004) “Phase sensitive continuous-wave THz imaging using diode lasers”, Electron. Lett., 40, 143-145.
2.27. Brown, E. R.; McIntosh, K. A.; Nichols, K. B., and Dennis, C. L.; (1995) “Photomixing up to 3.8 THz in lowtemperature-grown GaAs”, Appl. Phys. Lett., 66, 285-287.
2.28. Verghese, S.; K. McIntosh; Calawa, A. S.; Dinatale, W. F.; Duerr, E. K.; and Molvar, K. A., (1998) “Generation and detection of coherent terahertz waves using two photomixers”, Appl. Phys. Lett., 73, 3824-3826.
2.29. Gregory, I. S.; Tribe, W. R.; Cole, B. E.; Evans, M. J.; Linfield, E. H.; Davies, A. G.; and Missous, M.; (2004) “Resonant dipole antennas for continuous-wave terahertz photomixers”, Appl. Phys. Lett., 85, 1622-1624.
2.30. Ueda, A.; Noguchi, T.; Iwashita, H.; Sekimoto, Y.; Ishiguro, M.; Takano, S.; Nagatsuma, T.; Ito, H.; Hirata, A.; and Ishibashi, T., (2003) “W-band waveguide photomixer using a uni-traveling-carrier photodiode with 2-mW output,” IEEE Trans. Microwave Theory Tech. 51, 1455-1459.
2.31. Hirata, A.; Nagatsuma, T.; Yano, R.; Ito, H.; Furuta, T.; Hirota, Y.; Ishibashi, T.; Matsuo, H.; Ueda, A.; Noguchi, T.; Sekimoto, Y.; Ishiguro, M.; and Matsuura, S., (2002) “Output power measurement of photonic millimetre-wave and sub-millimetre-wave emitter at 100-800 GHz,” Electronics Lett. 38, 798-800.
2.32. Stohr, A.; Heinzelmann, R.; Hagedorn, K.; Gusten, R.; Schafer, F.; Stuer, H.; Siebe, F.; van der Wal, P.; Krozer, V.; Feiginov, M.; Jager, D., (2001) “Integrated 460GHz photonic transmitter module,”Electronics Lett. 37, 1347-1348.
2.33. Shi, J.-W.; Chu, S.-W.; Tien, M.-C.; Sun, C.-K.; Chiu, Y.-J.; and Bowers, J. E., (2002) “Edge-coupled membrane terahertz photonic transmitters based on metal-semiconductor-metal traveling photodetectors,” Appl. Phys. Lett., 81, 5108-5110.
2.34. Tien, M.-C.; Chang, H.-H.; Lu, J.-Y.; Chen, L.-J.; Chen, C.-Y.; Wu, R.-B.; Liu, W.-S.; Chyi, J.-I.; and Sun, C.-K., (2004) “Device saturation behavior of submillimeter-wave membrance photonic transmitters,” IEEE Photonics Technol. Lett., 16, 873-875.
2.35. Kao, T.-F.; Chang, H.-H.; Chen, L.-J.; Lu, J.-Y.; Liu, A.-S.; Yu, Y.-C.; Wu, R.-B.; Liu, W.-S.; Chyi, J.-I.; and Sun, C.-K., (2006) “Frequency tunability of terahertz photonic transmitter,” Appl. Phys. Lett., 88, 093501.
2.36. Shi, J.-W.; Gan, K.-G.; Yang, Y.-J.; Chen, Y.-H.; Sun, C.-K.; Yang, Y.-J.; and Bowers, J. E., (2001) “Metal-semiconductor-metal traveling-wave photodetectors,” IEEE Photonic Technology Letters 13, 623-625.
2.37. Shi J.-W.; and Sun, C.-K., (2000) "Design and analysis of long absorption length traveling wave photodetector," IEEE/OSA Journal of Lightwave Technology 18, 2176-2187.
2.38. Shi, J.-W.; Gan, K.-G.; Chen, Y.-H.; Sun, C.-K.; Chiu, Y.-J.; and Bowers, J. E., “Ultra-high power-bandwidth product and nonlinear photo-conductance performances of low-temperature-grown GaAs based metal-semiconductor-metal traveling-wave photodetectors,” IEEE Photonic Technology Letters 14 (11), pp. 1587-1589 (2002).
2.39. Tien, M.-C., (2003) Edge-coupled membrane terahertz photonic transmitters with high conversion efficiency, M.D. thesis, National Taiwan University, Institute of Electro-Optical Engineering.
2.40. Brown, E. R.; Smith, F. W.; and McIntosh, K. A.; (1993) “Coherent millimetre wave generation by heterodyne conversion in low-temperature-grown GaAs photoconductors”, J. Appl. Phys., 73, 1480-1484.
2.41. Weling, A.S.; Hu, B.B.; Froberg, N.M.; Auston, D.H., “Generation of tunable narrow-band THz radiation from large aperture photoconducting antennas,” (1994) Appl. Phys. Lett., 64, 137-139.
2.42. Liu, Y.; Park, S.-G.; and Weiner, A.M., (1996) “Enhancement of narrow-band terahertz radiation from photoconducting antennas by optical pulse shaping,” Opt. Lett. 21, 1762-1764.
2.43. Lu, J.-Y.; Chang, H.-H.; Chen, L.-J.; Tien, M.-C.; and Sun, C.-K., (2005) “Optoelectronic-Based High-Efficiency Quasi-CW Terahertz Imaging,” IEEE Photonics Technology Letters 17, 2406-2408.
2.44. Han, P. Y.; Cho, G. C.; and Zhang, X. C., (2000) “Time-domain transillumination of biological tissues with terahertz pulses,” Opt. Lett., 25, 242 –244.
2.45. Thrane, L.; Jacobsen, R.H.; Jepsen, P.U.; and Keiding, S.R., (1995) “THz reflection spectroscopy of liquid water,” Chem. Phys. Lett., 240, 330.
3.1. Song, X.; and Swanson, B. I., (1999) “Direct, ultrasensitive, and selective optical detection of protein toxins using multivalent interactions,” Anal. Chem., 71, 2097-2107.
3.2. Thompson, R. B.; and Jones, E. R., (1993) “Enzyme-based fiber optic zinc biosensor,” Anal. Chem., 65, 730 -734.
3.3. Wang, J., (2000) “From DNA biosensors to gene chips,” Nucleic Acids Res., 28, 3011–3016.
3.4. Masson, L.; Mazza, A.; Brousseau, R., (1994) “Stable immobilization of. lipid vesicles for kinetic studies using surface plasmon resonance,” Anal. Biochem., 218, 405-412.
3.5. Evan, T.; Ofer, L.; Wonill, H.; Moerner, W.E.; and James, S.H.J., (2004) “Integrated semiconductor vertical-cavity surface-emitting lasers and pin photodetectors for biomedical fluorescence sensing,” IEEE J. Quantum Electron. 40, 491–498.
3.6. Ocvirk, G.; Tang, T.; and Harrison D. J., (1998) “Optimization of confocal epifluorescence microscopy for microchip-based miniaturized total analysis systems,” The Analyst. 123, 1429-1434.
3.7. Nagel, M.; Bolivar, P. H.; Brucherseifer, M.; and Kurz, H., (2002) “Integrated THz technology for label-free genetic dioagnostics,” Appl. Phys. Lett. 80, 154.
3.8. Bolivar, P. H.; Brucherseifer, M.; Nagel, M.; Kurz; H., Bosserhoff, A.; and Buttner, R., (2002) “Label-free probing of genes by time-domain terahertz sensing,” Phys Med. Biol., 47, 3815-3821.
3.9. Nagel, M.; Richter, F.; Haring-Bol´ıvar, P.; and Kurz, H., (2003) “A functionalized THz sensor for marker-free DNA analysis,” Phys. Med. Biol. 48, 3625–3636.
3.10. Haring-Bol´ıvar, P.; Nagel, M.; Richter, F.; Brucherseifer, M.; Kurz, H., Bosserhoff, A.; and Buttner, R., (2004) “Label-free THz sensing of genetic sequences: towards ‘THz biochips’,” Phil. Trans. R. Soc. Lond. A, 362, 323-335.
3.11. Van Zandt, L. L.; and Saxena, V. K., (1989) “Millimeter-microwave spectrum of DNA—six predictions for spectroscopy,” Phys. Rev. A, 39, pp.2672-2674.
3.12. Zhuang, W.; Feng, Y.; and Prohofsky, E. W., (1990) “Self-consistent calculation of localized DNA vibrational properties at a double-helix–single-strand junction with anharmonic potential,” Phys. Rev. A, 41, pp.7033.
3.13. Bell, R. J., (1972) Introductory Fourier Transform Spectroscopy. Academic Press: New York.
3.14. Auston, D. H., (1975) “Picosecond optoelectronic switching and gating in silicon”, Appl Phys. Lett. 26, 101-103.
3.15. Wu, Qi; and Zhang, X.-C., (1996) “Design and characterization of traveling-wave electrooptic terahertz sensors,” IEEE J. Sel. Top. Quantum Electron., 2, 693-700.
3.16. Jiang, Z.; Li, M.; and Zhang, X.-C., (2000) “Dielectric constant measurement of thin films by differential time-domain spectroscopy,” Appl. Phys. Lett., 76, 3221-3223.
3.17. Mickan, S. P.; Menikh, A.; Liu, H.; Mannella, C. A.; MacColl, R.; Abbott, D.; Munch, J.; and Zhang, X.-C., (2002) “Label-free bioaffinity detection using terahertz technology,” Phys. Med. Biol., 47, 3789-3795.
3.18. Liron, Z.; Bromberg, A.; Fisher. M., (2000) Novel Approaches in Biosensors and Rapid Diagnostic Assays, Academic Press:New York, pp. 79-100, and 17-32.
3.19. Shi, J.-W.; Chu, S.-W.; Tien, M.-C.; Sun, C.-K.; Chiu, Y.-J.; and Bowers, J. E., (2002) “Edge-coupled membrane terahertz photonic transmitters based on metal-semiconductor-metal traveling photodetectors,” Appl. Phys. Lett., 81, 5108-5110.
3.20. Tien, M.-C.; Chang, H.-H.; Lu, J.-Y.; Chen, L.-J.; Chen, C.-Y.; Wu, R.-B.; Liu, W.-S.; Chyi, J.-I.; and Sun, C.-K., (2004) “Device saturation behavior of submillimeter-wave membrance photonic transmitters,” IEEE Photonics Technol. Lett., 16, 873-875.
3.21. Kao, T.-F.; Chang, H.-H.; Chen, L.-J.; Lu, J.-Y.; Liu, A.-S.; Yu, Y.-C.; Wu, R.-B.; Liu, W.-S.; Chyi, J.-I.; and Sun, C.-K., (2006) “Frequency tunability of terahertz photonic transmitter,” Appl. Phys. Lett., 88, 093501.
3.22. Shi, J.-W.; Gan, K.-G.; Yang, Y.-J.; Chen, Y.-H.; Sun, C.-K.; Yang, Y.-J.; and Bowers, J. E., (2001) “Metal-semiconductor-metal traveling-wave photodetectors,” IEEE Photonic Technology Letters 13, 623-625.
3.23. Shi J.-W.; and Sun, C.-K., (2000) "Design and analysis of long absorption length traveling wave photodetector," IEEE/OSA Journal of Lightwave Technology 18, 2176-2187.
3.24. Shi, J.-W.; Gan, K.-G.; Chen, Y.-H.; Sun, C.-K.; Chiu, Y.-J.; and Bowers, J. E., “Ultra-high power-bandwidth product and nonlinear photo-conductance performances of low-temperature-grown GaAs based metal-semiconductor-metal traveling-wave photodetectors,” IEEE Photonic Technology Letters 14 (11), pp. 1587-1589 (2002).
3.25. Weling, A. S.; and Auston, D. H., (1996) “Novel sources and detectors for coherent tunable narrow-band terahertz radiation in free space,” J. Opt. Soc. Am. B, 13, 2783-2791.
3.26. Lu, J.-Y.; Chen, L.-J.; Kao, T.-F.; Chang, H.-H.; Chen, H.-W.; Liu, A.-S.; Yu, Y.-C.; Wu, R.-B.; Liu, W.-S.; Chyi, J.-I.; and Sun, C.-K., (2006) “Terahertz microchip for illicit drug detection,” IEEE Photonics Technology Letters 18, 2254-2256.
3.27. Lee, G.-B. Chen, S.-H. Huang, G.-R.; Sung, W. C.; and Lin, Y.-H., (2001) “Microfabricated plastic chips by hot embossing methods and their applications for DNA separation and detection,” Sens. Actuator B-Chem., 75, 142 –148.
3.28. Pieper and Rutledge, Laboratory Techniques for Pharmacists, Upjohn 1989, page 47, table 3.
3.29. Williams, R.H.; Maggiore, J.A.; Shah, S.M.; Erickson, T.B.; and Negrusz, A., (2000) “Cocaine and its major metabolites in plasma and urine samples from patients in an urban emergency medicine setting,” J. Anal. Toxicol., 24, 478-481.
3.30. Kraemer, T.; Theis, G.A.; Weber, A.A.; and Maurer, H.H., (2000) ”Studies on the metabolism and toxicological detection of the amphetamine-like anorectic fenproporex in human urine by gas chromatography-mass spectrometry and fluorescence polarization immunoassay,” J. Chromatogr. B: Biomed. Sci. Appl., 738, 107-118.
3.31. Weling, A.S.; Hu, B.B.; Froberg, N.M.; Auston, D.H., “Generation of tunable narrow-band THz radiation from large aperture photoconducting antennas,” (1994) Appl. Phys. Lett., 64, 137-139.
3.32. Chen, L.-J., (2005) Terahertz subwavelength fiber, M.D. thesis, National Taiwan University, Institute of Electro-Optical Engineering.
3.33. Chen, L. -J.; Kao, T. -F.; Lu, J. -Y.; and Sun, C. -K., (2006) "A simple terahertz spectrometer based on a low-reflectivity Fabry-Perot interferometer using Fourier transform spectroscopy," Opt. Express, 14, 3840-3846.
3.34. Kawase, K.; Ogawa, Y.; Minamide, H.; and Ito, H., (2005) “Terahertz parametric sources and imaging applications,” Semicond. Sci. Technol., 20, S258-S265.
3.35. Fischer, B.; Hoffmann, M.; Helm, H.; Modjesch, G.; and Uhd Jepsen, P., (2005) “Chemical recognition in terahertz time-domain spectroscopy and imaging,” Semicond. Sci. Technol., 20, S246-S253.
3.36. Chan, T.L.J.; Bjarnason, J.E.; Lee, A.W.M.; Celis, M.A.; and Brown, E.R., (2004) “Attenuation contract between biomolecular and inorganic materials at terahertz frequencies”, Appl. Phys. Lett., 85, 2523.
3.37. Thrane, L.; Jacobsen, R. H.; Uhd Jepsen, R. H.; Keiding, S. R., (1995) “THz reflection spectroscopy of liquid water,” Chem. Phys. Lett. , 240, 330-333.
4.1. Gallot, G.; Jamison, S. P.; McGowan R.W.; and Grischkowsky, D., (2000) “Terahertz waveguides.” J. Opt. Soc. Am. B, 17, 851-863.
4.2. Harrington, J.; George, R.; Pedersen, P.; and Mueller, E., (2004) “Hollow polycarbonate waveguides with inner Cu coatings for delivery of terahertz radiation,” Opt. Express, 12, 5263-5268.
4.3. Hidaka, T., (2003) “Ferroelectric PVDF cladding THz waveguide,” Proc. SPIE, 5135, 70-77.
4.4. Hidaka, T.; Minamide, H.; Ito, H.; Nishizawa, J.; Tamura, K.; and Ichikawa, S.; (2005) “Ferroelectric PVDF Cladding Terahertz Waveguide,” J. Lightwave Technol. 23, 2469-2473.
4.5. Mendis, R.; and Grischkowsky, D., (2001) “Undistorted guided-wave propagation of subpicosecond terahertz pulses,” Optics Letters, 26, 846–848.
4.6. Mendis, R.; and Grischkowsky, D., (2001) “THz interconnect with low-loss and low-group velocity dispersion,” IEEE Microwave and Wireless Components Letters 26, 444–446.
4.7. Jeon, T.-I.; and Grischkowsky, D., (2004) “Direct optoelectronic generation and detection of sub-ps-electrical pulses on sub-mm-coaxial transmission lines,” Applied Physics Letters, 85, 6092–6094.
4.8. Wang, K.; and Mittleman, D. M.; (2004) “Metal wires for terahertz wave guiding,” Nature, 432, 376–379.
4.9. Jeon, T.-I.; Zhang, J.; and Grischkowsky, D., (2005) “THz Sommerfeld wave propagation on a single metal wire,” Applied Physics Letters. 86, 161904.
4.10. Bingham, A.; Zhao, Y.; and Grischkowsky, D., (2005) “THz parallel plate photonic waveguide,” Applied Physics Letters, 87, 051101.
4.11. Jeon T.-I.; and Grischkowsky, D., (2006) “THz Zenneck surface wave (THz surface plasmon) propagation on a metal sheet,” Applied Physics Letters, 88, 061113.
4.12. Frankel, M. Y.; Gupta, S.; Valdmanis, J. A.; and Mourou, G. A., (1991) “Terahertz attenuation and dispersion characteristics of coplanar transmission lines,” IEEE Trans. Microwave Theory Tech., 39, 910-916.
4.13. McGowan, R. W.; Gallot, G.; and Grischkowsky, D., (1999) "Propagation of ultrawideband short pulses of terahertz radiation through submillimeter-diameter circular waveguides," Opt. Lett., 24, 1431-1433.
4.14. Cao H.; and Nahata, A., (2005) “Coupling of terahertz pulses onto a single metal wire waveguide using milled grooves” Opt. Express, 13, 7028-7034.
4.15. Chen, L.-J.; Chen, H.-W.; Kao, T.-F.; Lu, J.-Y.; and Sun, C.-K., (2006) “Low-loss Subwavelength Plastic Fiber for Terahertz Wave Guiding,” Optics Letters, 31, 308-310.
4.16. Mendis, R.; and Grischkowsky, D.; (2000) “Plastic ribbon THz waveguides,” J. Appl. Phys., 88, 4449-4451.
4.17. Jamison, S. P.; McGowan, R. W.; and Grischkowsky, D., (2000) “Single-mode waveguide propagation and reshaping of sub-ps terahertz pulses in sapphire fibers,” Appl. Phys. Lett., 76, 1987-1989.
4.18. Han, H.; Park, H.; Cho, M.; and Kim, J., (2002) “Terahertz pulse propagation in a plastic photonic crystal fiber,” Appl. Phys. Lett., 80, 2634-2636.
4.19. Goto, M.; Quema, A.; Takahashi, H.; Ono, S.; and Sarukura, N., (2004) “Teflon photonic crystal fiber as terahertz waveguide,” Jpn. J. Appl. Phys., Part 1 43, L317-L319.
4.20. Chen, H.-W. Li, Y.-T.; Kuo, J.-L.; Lu, J.-Y.; Chen, L.-J.; Pan, C.-L.; and Sun, C.-K., (2007) “Investigation on spectral loss characteristics of subwavelength terahertz fibers,” Optics Letters, 32, 1017-1019.
4.21. Yu, C. P.; and Chang, H.C., (2004) “Yee-Mesh-Based Finite Difference Eigenmode Solver with PML Absorbing Boundary Conditions for Optical Waveguides and Photonic Crystal Fibers,” Optics Express, 12, 6165-6177.
4.22. Yu, C.-P. et al. (2007) “Analysis of air-core Terahertz waveguides,” CLEO-PR, Korea.
4.23. Birch, J. R.; Dromey, J. D.; and Lesurf, J., (1981) “The optical constants of some common low-loss polymers between 4 and 40 cm-1,” Infrared Phys., 21, 225–228.
4.24. White, T. P.; McPhedran, R. C.; Sterke, C. M.; Litchinitser, N. M.; and Eggleton, B. J., (2002) "Resonance and scattering in microstructured optical fibers," Opt. Lett., 27, 1977-1979.
4.25. Lu, J. Y.; Yu, C. P.; Chang, H. C.; Chen, H. W.; Li, Y. T.; Pan, C. L.; and Sun, C. K., (2007) “Air-core microstructure fiber for terahertz radiation waveguiding,” in Proc. CLEO/QELS 2007, Baltimore, MD.
4.26. Martin, D. H.; and Puplett, E., (1969) “Polarised interferometric spectrometry for the the millimetre and submillimetre spectrum,” Infrared Physics, 10, 105-109.
4.27. Smith, P. R.; Auston, D. H.; and Nuss, M. C.; (1988) “Subpicosecond photoconductive dipole antennas”, IEEE J. Quantum Electron, 24, 255-260.
4.28. Chen, H.-W., (2006) Single mode fiber-based THz directional coupler, M.D. thesis, National Taiwan University, Institute of Electro-Optical Engineering.
4.29. Griffiths, P.; James, A.; and Haseth, D., (1986) Fourier Transform Infrared Spectrometry, John Wiley & Sons.
5.1. Chen, L.-J.; Chen, H.-W.; Kao, T.-F.; Lu, J.-Y.; and Sun, C.-K., (2006) “Low-loss Subwavelength Plastic Fiber for Terahertz Wave Guiding,” Optics Letters, 31, 308-310.
5.2. Chen, H.-W. Li, Y.-T.; Kuo, J.-L.; Lu, J.-Y.; Chen, L.-J.; Pan, C.-L.; and Sun, C.-K., (2007) “Investigation on spectral loss characteristics of subwavelength terahertz fibers,” Optics Letters, 32, 1017-1019.
5.3. Chen, L.-J., (2005) Terahertz subwavelength fiber, M.D. thesis, National Taiwan University, Institute of Electro-Optical Engineering.
5.4. Chen, H.-W., (2006) Single mode fiber-based THz directional coupler, M.D. thesis, National Taiwan University, Institute of Electro-Optical Engineering.
5.5. Yariv, A., (1997) Optical Electronics in Modern Communications, Oxford University Press, fifth edition, New York.
5.6. Lamb, J. W.; (1996) “Miscellaneous data on materials for millimetre and submillimetre optics,” Int. J. Infra. Milli. Waves 17, 1997-2034.
5.7. Tong, L.; Lou, J.; and Mazur, E., (2004) “Single-mode guiding properties of subwavelength-diameter silica and silicon wire waveguides,” Opt. Express, 12, 1025-1035.
5.8. Elsasser, W. M. (1949) "Attenuation in a dielectric circular rod," J. Appl. Phys. 20, 1193.
5.9. Han, C. D.; and Lamonte, R. R., (1972) “Studies on melting spinning. I. Effect of molecular structure and molecular weight distribution on elongation viscosity,” J. rheol. (N.Y. N.Y.) , 16, 447-472.
5.10. Weling, A. S.; and Auston, D. H., (1996) “Novel sources and detectors for coherent tunable narrow-band terahertz radiation in free space,” J. Opt. Soc. Am. B, 13, 2783-2791.
5.11. Kao, T.-F.; Chang, H.-H.; Chen, L.-J.; Lu, J.-Y.; Liu, A.-S.; Yu, Y.-C.; Wu, R.-B.; Liu, W.-S.; Chyi, J.-I.; and Sun, C.-K., (2006) “Frequency tunability of terahertz photonic transmitter,” Appl. Phys. Lett., 88, 093501.
5.12. Crowe, T.W.; Bishop, W. L.; Porterfield, D. W.; Hesler, J. L.; and Weikle, R. M., (2005) “Opening the terahertz. window with integrated diode circuits,” IEEE J. Solid States Circuits., 40, 2104-2110.
5.13. Carlstrom, J. E.; Plambeck, R. L.; and Thornton, D. D. (1985) “A continuously Tunable 65-115 GHz Gunn Oscillator,” IEEE Trans. Microwave Theory and Tech., 33, 610-619.
5.14. Golay cells, Inc., Microtech Instruments, Eugene, www.mtinstruments.com.
5.15. Liu, T.-M.; Lu, J.-Y.; Murray, D. B.; Lai, C.-W.; Yang, M.-J.; Chen, H.-P.; Kuo, C.-C.; Saviot, L.; Hwang, Y.-J.; Chang, M.-H.; Liu, H.-L.; Liu, W.-S.; Chyi, J.-I.; Chou, P.-T.; and Sun,C.-K., (2007) “Type-II Nanocrystals as Contrast Agents of Sub-Terahertz Imaging” submitted to Nanotechnology.
5.16. Chen, C.-Y. et al., (2005) “Type-II CdSe/CdTe/ZnTe (core–shell–shell) quantum dots with cascade band edges: The separation of electron (at CdSe) and hole (at ZnTe) by the CdTe layer,” Small, 1, 1215-1220.
5.17. Kim, S.; Fisher B.; Eisler, H.-J.; and Bawendi, M., (2003) “Type-II quantum dots: CdTe/CdSe (core/shell) and CdSe/ZnTe (core/shell) heterostructures,” J. Am. Chem. Soc. 125, 11466-11467.
5.18. Eringen, A. C.; and Suhubi, E. S., (1975) Elastodynamics Academic Press: New York.
5.19. Chiang, P. J.; Yang, C. S.; Wu, C. L.; Teng, C. H.; and Chang, H. C., (2005) “Application of Pseudospectral Methods to Optical Waveguide Mode Solvers,” in OSA 2005 Integrated Photonics Research and Applications (IPRA '05), Technical Digest (CD-ROM), paper IMG4, San Diego, California, April 11-13. | en |