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1996. Vol. 21, № 24.P. 2011ҫ2013.118. Mittleman D. M., Jacobsen R. H., Neelamani R. et al. Gas sensing using terahertz time-domain spectroscopy // Applied Physics B. 1998. Vol. 67, № 3.P. 379ҫ390.119. Component spatial pattern analysis of chemicals using terahertz spectroscopic imaging / Y. Watanabe [et al.] // Applied Physics Letters. 2003.Vol. 83, № 4.
P. 800ҫ802.120. Using terahertz pulse spectroscopy to study the crystalline structure of adrug: a case study of the polymorphs of ranitidine hydrochloride / P. F. Taday [et al.] // Journal of Pharmaceutical Sciences. 2003. Vol. 92, № 4.P. 831ҫ838.121. Taday P. F. Applications of terahertz spectroscopy to pharmaceutical sciences // Philosoҥcal Transactions A. 2004. Vol. 362.
P. 351ҫ364.122. Terahertz pulsed spectroscopy and imaging in the pharmaceutical setting a review / J. A. Zeitler [et al.] // Journal of Pharmacy and Pharmacology.2007. Vol. 59, № 2. P. 209ҫ223.123. Shen Y.-C. Terahertz pulsed spectroscopy and imaging for pharmaceuticalapplications: A review // International Journal of Pharmaceutics. 2011.Vol. 417. P.
48ҫ60.124. Terahertz spectroscopy for pharmaceutical applications / L. M. Ingle [et al.] // International Journal of Pharmacy and Pharmaceutical ScienceResearch. 2013. Vol. 3, № 1. P. 48ҫ52.125. Nave R. Interaction of Radiation with Matter // http://hyperphysics.phyastr.gsu.edu/hbase/hframe.html:ПорталHyperPhysics.URL.http://hyperphysics.phy-astr.gsu.edu/hbase/mod3.html(датаобращения: 15.05.2016 г.).126. Prediction of an extremely large nonlinear refractive index for crystals atterahertz frequencies / K. Dolgaleva [et al.] // Physical Review A. 2015.Vol. 92. P. 023809.127.
Fischer B. M., Walther M., Uhd Jepsen P. Far-infrared vibrational modes ofDNA components studied by terahertz time-domain spectroscopy // Physicsin Medicine and Biology. 2002. Vol. 47, № 21. P. 3807ҫ3814.147128. Wei-Ning W., Guo W., Yan Z. Low-frequency vibrational modes of glutamine // Chinese Physics B. 2011. Vol. 20, № 12. P. 123301.129. Platte F., Heise H. M. Substance identiҥcation based on transmission THzspectra using library search // Journal of Molecular Structure. 2014.Vol. 1073.
P. 3ҫ9.130. Collective vibrational modes in biological molecules investigated by terahertz time-domain spectroscopy / M. Walther [et al.] // Biopolymers. 2002.Vol. 67, № 4ҫ5. P. 310ҫ313.131. Optical characteristics of biological molecules in the terahertz gap /T. Globus [et al.] // Proceedings of SPIE.
2004. Vol. 5584. P. 1ҫ10.132. Microѕuidic devices for terahertz spectroscopy of biomolecules /P. A. George [et al.] // Optics Express. 2008. Vol. 16, № 3. P. 1577ҫ1582.133. Molecular imaging with terahertz waves / S. J. Oh [et al.] // Optics Express.2011. Vol.
19, № 5. P. 4009ҫ4016.134. Son J.-H. Principle and applications of terahertz molecular imaging // Nanotechnology. 2013. Vol. 24, № 21. P. 214001.135. Medical applications of broadband terahertz pulsed radiation / A. Fitzgerald [et al.] // Lasers and Electro-Optics Society, 2005. LEOS 2005. The 18thAnnual Meeting of the IEEE. 2005. P.
120ҫ121.136. Clothier R. H., Bourne N. Efects of THz exposure on human primary keratinocyte diferentiation and viability // Journal of Biological Physics. 2003.Vol. 29, № 2ҫ3. P. 179ҫ185.137. Terahertz radiation increases genomic instability in human lymphocytes /A. Korenstein-Ilan [et al.] // Radiation Research.
2008. Vol. 170, № 2.P. 224ҫ234.138. Study of terahertz-radiation-induced DNA damage in human blood leukocytes / A. A. Angeluts [et al.] // Quantum Electronics. 2014. Vol. 44, № 3.P. 247ҫ251.139. High-power femtosecond-terahertz pulse induces a wound response in mouseskin / A.
Korenstein-Ilan [et al.] // Scientiҥc Reports. 2013. Vol. 3. P. 2296.140. In vivo analysis of THz wave irradiation induced acute inѕammatory response in skin by laser-scanning confocal microscopy / Y. Hwang [et al.] //Optics Express. 2014. Vol. 22, № 10. P. 11465ҫ11475.148141. Intense THz pulses down-regulate genes associated with skin cancer andpsoriasis: a new therapeutic avenue? / L. V. Titova [et al.] // ScientiҥcReports. 2013. Vol. 3. P. 2363.142.
Berry E. Risk perception and safety issues // Journal of Biological Physics.2003. Vol. 29, № 2ҫ3. P. 263ҫ267.143. Vecchia P. Perception of risks from electromagnetic ҥelds: lessons for thefuture // Journal of Biological Physics. 2003. Vol. 29, № 2ҫ3. P. 269ҫ274.144. International commission on non-ionizing radiation protection: guidelineson limits of exposure to laser radiation of wavelengths between 180 nm and1,000 µm // Health Physics.
1996. Vol. 71, № 5. P. 804ҫ819.145. Guidelines for limiting exposure to time-varying electric, magnetic, and electromagnetic ҥelds (up to 300 GHz) / A. Ahlbom [et al.] // Health Physics.1998. Vol. 74, № 4. P. 494ҫ522.146. Standard for safety levels with respect to human exposure to radiofrequencyelectromagnetic ҥelds, 3 kHz to 300 GHz. USA Standard IEEE C95.1 ҫ 1991Edition.
United States of America, 1991.147. American national standards institute: american national standard for safeuse of lasers. USA Standard ANSI Z136.1 ҫ 1993 Edition. United States ofAmerica, 1993.148. Standard for safety levels with respect to human exposure to radiofrequencyelectromagnetic ҥelds, 3 kHz to 300 GHz. USA Standard IEEE C95.1 ҫ 1999Edition. United States of America, 1999.149. American national standards institute: american national standard for safeuse of lasers. USA Standard ANSI Z136.1 ҫ 2000 Edition.
United States ofAmerica, 2000.150. Safety of laser products. European Standard EN 60825 ҫ 1:2007. UnitedKingdom, 2007.151. Do in vivo terahertz imaging systems comply with safety guidelines? /E. Berry [et al.] // Journal of Laser Applications. 2003. Vol. 15, № 3.P. 192ҫ198.152. Harris F. On the use of windows for harmonic analysis with the discreteFourier transform // Proceedings of the IEEE. 1978. Vol.
66, № 1. P. 51ҫ83.153. Gonzalez R. C., Woods R. E. Digital Image Processing. 3rd Edition. UnitedStates of America: Prentice Hall, 2007. 954 p.149154. Hossain A., Rashid M. H. Pyroelectric detectors and their applications //IEEE Transactions on Industry Applications. 1991. Vol.
27, № 5. P. 824ҫ829.155. Beerman H. P. The pyroelectric detector of infrared radiation // IEEE Transactions on Electron Devices. 1969. Vol. 16, № 6. P. 554ҫ557.156. Richards P. L. Bolometers for infrared and millimeter waves // Journal ofApplied Physics. 1994. Vol. 76, № 1. P. 1ҫ24.157. Gruner G.
Millimeter and submillimeter wave spectroscopy of solids. Berlin,Germany: Springer-Verlag, 1998. 290 p.158. Tsimring S. E. Electron beams and microwave vacuum electronics. Hoboken,United States of America: John Wiley & Sons, 2007. 573 p.159. BWO generators for terahertz dielectric measurements / G. A. Komandin [et al.] // IEEE Transactions on Terahertz Science and Technology.2013. Vol. 3, № 4. P. 440ҫ444.160. Piestrup M.
A., Fleming R. N., Pantell R. H. Continuously tunable submillimeter wave source // Applied Physics Letters. 1975. Vol. 26, № 8.P. 418ҫ421.161. Coherent tunable THz-wave generation from LiNbO3 with monolithic grating coupler / K. Kawase [et al.] // Applied Physics Letters. 1996.Vol. 68, № 18. P. 2483ҫ2485.162. Unidirectional radiation of widely tunable THz wave using a prism couplerunder noncollinear phase matching condition / K. Kawase [et al.] // AppliedPhysics Letters. 1997. Vol.
71, № 6. P. 753ҫ755.163. Injection-seeded terahertz-wave parametric oscillator / K. Imai [et al.] //Applied Physics Letters. 2001. Vol. 78, № 8. P. 1026ҫ1028.164. Terahertz wave parametric source / K. Kawase [et al.] // Journal of PhysicsD: Applied Physics.
2002. Vol. 35, № 3. P. R1ҫR14.165. Achromatically injection-seeded terahertz-wave parametric generator /K. Imai [et al.] // Optics Letters. 2002. Vol. 27, № 24. P. 2173ҫ2175.166. Tunable terahertz-wave parametric oscillators using LiNbO3 andMgO:LiNbO3 crystals / J.ҫI. Shikata [et al.] // IEEE Transactions onMicrowave Theory and Techniques. 2000. Vol. 48, № 4.
P. 653ҫ661.167. Transform-limited, narrow-linewidth, terahertz-wave parametric generator /K. Kawase [et al.] // Applied Physics Letters. 2001. Vol. 78, № 19. P. 2819ҫ2821.150168. Tabletop terahertz-wave parametric generator using a compact, diodepumped Nd:YAG laser / A. Sato [et al.] // Review of Scientiҥc Instruments.2001. Vol. 72, № 9. P. 3501ҫ3504.169. Injection-seeded terahertz-wave parametric generator with wide tunability /K. Kawase [et al.] // Applied Physics Letters. 2002. Vol.
80, № 2. P. 195ҫ197.170. Compact source of continuously and widely-tunable terahertz radiation. /T. Edwards [et al.] // Optics Express. 2006. Vol. 14, № 4. P. 1582ҫ1589.171. Output power enhancement of a palmtop terahertz-wave parametric generator / S. Hayashi [et al.] // Applied Optics. 2007. Vol. 46, № 1. P. 117ҫ123.172. Tunability enhancement of a terahertz-wave parametric generator pumpedby a microchip Nd:YAG laser / S. Hayashi [et al.] // Applied Optics.
2009.Vol. 48, № 15. P. 2899ҫ2902.173. Brown E. R., Smith F. W., McIntosh K. A. Coherent millimeter-wave generation by heterodyne conversion in low-temperature-grown GaAs photoconductors // Journal of Applied Physics. 1993. Vol. 73, № 3. P. 1480ҫ1484.174. Verghese S., Mcintosh K., Brown E.















