350 rub
Journal Radioengineering №10 for 2014 г.
Article in number:
Development of O-type amplifiers and oscillators in sub-terahertz band
Keywords: traveling wave tube sheet electron beam terahertz band field-emission cathode
Authors:
T.A. Karetnikova - Post-graduate student, Saratov State University named after N.G. Chernyshevskii. E-mail: KaretnikovaT@mail.ru
A.G. Rozhnev - Senior researcher, Saratov State University. E-mail: RozhnevAG@info.sgu.ru
N.M. Ryskin - Dr.Sc. (Phys.-Math.), professor, Saratov State University named after N.G. Chernyshevskii. E-mail: RyskinNM@info.sgu.ru
G.V. Torgashov - Ph.D. (Phys.-Math.), Head of Laboratory, Saratov Branch, V.A. Kotelnikov Institute of Radio Engineering and Electronics RAS. E-mail: TorgashovGV@gmail.com
I.G. Torgashov - Ph.D. (Phys.-Math.), Senior researcher, Saratov Branch of V.A. Kotelnikov Institute of Radio Engineering and Electronics RAS. E-mail: TorgashovIG@gmail.com
N.I. Sinitsyn - Dr.Sc. (Phys.-Math.), Vice-director, Saratov Branch of V.A. Kotelnikov Institute of Radio Engineering and Electronics RAS. E-mail - SinitsynNI@gmail.com
Abstract:
Results of research aimed on development of miniaturized O-type medium power amplifiers and oscillators in sub-THz band are presented. Dispersion characteristics and coupling impedances for planar grating slow-wave structures are calculated. Design issues of a field-emission electron source are considered.
Pages: 46-51
References

  1. Rozhnev A.G., Ryskin N.M., Sokolov D.V., Trubetskov D.I., Han S.T., Kim J.I., Park G.S. Novel concepts of vacuum microelectronic microwave devices with field emitter cathode arrays // Physics of Plasmas. 2002. Vol. 9, No. 9. P. 4020‑4027.
  2. Ives R.L. Microfabrication of high-frequency vacuum electron devices // IEEE Trans. Plasma Sci. 2004. Vol. 32, No. 3. P. 1277-1291.
  3. Srivastava V. THz vacuum microelectronic devices // J. Physics: Conf. Series. 2008. Vol. 114, No.1. 012015.
  4. Booske J.H., Dobbs R.J., Joye C.D., Kory C.L., Neil G.R., Park G.S., Park J.H., Temkin R.J. Vacuum electronic high power terahertz sources // IEEE Trans. Terahertz Sci. Technol. 2011. Vol. 12, No. 1. P. 54-75.
  5. Carlsten B.E., Russell S.J., Earley L.M., Krawczyk F.L., Potter J.M., Ferguson P., Humphries S. Technology development for a mm-wave sheet-beam traveling-wave tube // IEEE Trans. Plasma Sci. 2005. Vol. 33, No.1. P. 85-93.
  6. Shin Y.M., Barnett L.R. Luhmann N.C. Phase-shifted traveling-wave-tube circuit for ultrawideband high-power submillimeter-wave generation // IEEE Trans. Electron Devices. 2009. Vol. 56, No. 5. P. 706-712.
  7. Shin Y.-M., Baig A., Barnett L.R., Tsai W.-C., Luhmann N.C., Pasour J., Larsen P. Modeling investigation of an ultrawideband terahertz sheet beam traveling-wave tube amplifier circuit // IEEE Trans. Electron Devices. 2011. Vol. 58, No. 9. P. 3213-3219.
  8. Shin Y.-M., Baig A., Barnett L.R., Tsai W.-C., Luhmann N.C. System design analysis of a 0.22-THz sheet-beam traveling-wave tube amplifier // IEEE Trans. Electron Devices. 2012. Vol. 59, No. 1. P. 234-240.
  9. Joye C.D., Calame J.P., Cook A.M., Garven M. High-power copper gratings for a sheet-beam traveling-wave amplifier at G-band // IEEE Trans. Electron Devices. 2013. Vol. 60, No. 1. P. 506-509.
  10. Wang Zh., Gong Y., Wei Y., Duan Zh., Zhang Y., Yue L., Gong H., Yin H., Lu Zh., Xu J., Feng J. High-power millimeter-wave BWO driven by sheet electron beam // IEEE Trans. Electron Devices. 2013. Vol. 60, No. 1. P. 471-477.
  11. Rozhnev A.G., Ryskin N.M., Karetnikova T.A., Torgashov G.V., Sinitsyn N.I., Shalaev P.D., Bourtsev A.A. Issledovanie kharakteristik zamedlyayushchei sistemy lampy begushchei volny millimetrovogo diapazona s lentochnym elektronnym puchkom // Izv. vuzov. Radiofizika. 2013. Vol. 56, No. 8-9. P. 601-613. (in Russian)
  12. Wolfram Research, Inc., Mathematica, Version 6.0, Champaign, IL (2007).
  13. Karetnikova T.A., Rozhnev A.G., Ryskin N.M., Torgashov G.V., Sinitsyn N.I., Shalaev P.D., Bourtsev A.A.. Modeling of eigenwaves in single- and double-vane slow-wave structures for sheet-beam sub-THz devices // 15th IEEE International Vacuum Electronics Conference. Monterey, CA, USA, April 22-24, 2014. P. 493-494.
  14. Silin R.A., Sazonov V.P. Zamedlyayushchie sistemy. Moscow: Sov. radio, 1966. 632 p.
  15. Spindt C. A., Brodie I., Humphrey L., Westerberg E.R. Physical properties of thin-film field emission cathodes with molybdenum cones // J. Appl. Phys. 1976. Vol. 47. P. 5248.
  16. Sinitsyn N.I., Gulyaev Yu.V., Devyatkov N.D., Torgashov G.V., Grigoriev Yu.A., Zakharchenko Yu.F., Zhbanov A.I., Chernozatonskii L.A., Knyazev S.A., Kosakovskaya Z.Ya., Torgashov I.G. Uglerodnye nanoklasternye struktury - odin iz materialov emissionnoi elektroniki budushchego // Radiotekhnika. 2000. No. 2. P. 9-18. (in Russian)
  17. Sinitsyn N.I., Torgashov G.V., Torgashov I.G., Baiburin V.B., Buyanova Z.I., Zhbanov A.I. Novyi avtoemissionnyi material - tonkie uglerodnye nanoklasternye plenki: tekhnologicheskie aspekty // Geteromagnitnaya mikroelektronika. 2013. Iss. 14. P. 13-23. (in Russian)
  18. Gulyaev Yu.V., Sinitsyn N.I., Torgashov G.V., Zhbanov A.I., Torgashov I.G., Savelyev S.G. Avtoelektronnaya emissiya s uglerodnykhnanotrubnykhplenok // RadiotekhnikaIelektronika. 2003. Vol. 48. P. 1399-1406. (in Russian)
  19. TorgashovI.G., TorgashovG.V., SinitsynN.I., BaiburinV.B. Raschetvliyaniyaformirovaniyapatternaemitiruyushchegomaterialanapoverkhnostiavtokatodanatokelektronnoiavtoemissii // Geteromagnitnayamikroelektronika. 2013. Iss. 14. P. 53-57. (inRussian)