350 rub
Journal №4 for 2015 г.
Article in number:
X-Ray nanophotonics on base of the planar X-Ray waveguide-resonators
Keywords: X-Ray beams X-Ray waveguide-resonators nanosize standing wave nanophotonics
Authors:
V.K. Egorov - Ph.D. (Phys.-Math.), Senior Research Scientist, Institute of MicroTechnology RAS, Moscow - Chernogolovka, Russia. E-mail: egorov@iptm.ru E.V. Egorov - Junior Research Scientist, Institute of MicroTechnology RAS, Moscow - Chernogolovka, Russia. E-mail: hed1317@mail.ru M.S. Afanas'ev - Ph.D. (Eng.) , Senior Research Scientist, Fryasino branch of Institute of Radiotechnics and Electronics RAS, Moscow- Fryazino, Russia. E-mail: michaela2005@yandex.ru E.M. Loukianchenko - Ph.D. (Phys.-Math.), Scientist Lider of Firm «Polus», Sankt-Peterburg, Russia. E-mail: emluk@mail.ru
Abstract:
X-Ray nanophotonics is the new direction of x-Ray optics connected with x-Ray nanosize beams formation and its practical utilization. Best efficiency of a similar beams formation was achieved at using of the planar x-Ray waveguide-resonators (PXWR) application. The work presents description of device designs, and the mechanism of its function is discussed. Work gives estimate of PXWR advantages and shortcomings and device efficiency increasing. There are presented the experimental proof of possibility to operate by parameters of x-Ray nanosize beam formed by PXWR in result of external influence on the interference field of x-Ray standing wave arising in its planar extended slit clearance, firstly. The work demonstrates high efficiency of PXWR application for development of total x-Ray fluorescence analysis.
Pages: 43-51
References

 

  1. Valiev K.A. Fizika submikronnojj litografii. M.: Nauka. 1990. 528 s.
  2. Broudajj I., Merejj Dzh. Fizicheskie osnovy mikrotekhnologii. M.: Mir. 1985. 494 s.
  3. Belaja kniga po nanotekhnologijam, issledovanija v oblasti nanochastic, nanostruktur i nanokompozitov v RF / Pod. red. V.I.Arzhanceva i dr. M.: LKI. 2008. 344 s.
  4. Feldman A., Majjer D. Osnovy analiza poverkhnosti i tonkikh plenok. M.: Mir. 1989. 342 s.
  5. Novotnyjj L., KHekht B. Osnovy nanooptiki. M.: Fizmatlit. 2009. 482 s.
  6. Klockenkamper R., von Bohlen A. Total x-ray fluorescence analysis and related methods. New York: Wiley. 2015. 519 p.
  7. Modern developments in X-ray and neutron optics / Eds. Erko A., Idir M., Krist T., Michette A.G. Berlin: Springer. 2008. 533 p.
  8. Balz A.V. Fresnel zone plate for optical image formation using extreme ultraviolet soft x-ray radiation // J. Opt. Soc. Am. 1961. V. 51. p. 405-412.
  9. Snigerev A., Kohn V., Snigereva L., Lengeler B.A. A compaund refractive lens for focusing high energy x-ray // Nature. 1996. V. 384. R. 49-51.
  10. Jark W., Di Fonzo S., Logomarsino S., Cedola A. and all. Properties of a submicrometer X-ray beam at the exit of a waveguide // Appl. Phys. 1996. V. 80. № 9. R. 4831-4836.
  11. Egorov V.K., Egorov E.V. Planar X-ray waveguide-resonator features // Trends in Appl. Spec. 2010. V. 8. P. 67-83.
  12. Egorov V.K., Egorov E.V. Tekhnologicheskie aspekty postroenija ploskogo rentgenovskogo volnovoda-rezonatora // Poverkhnost (rentg., sinkhr., nejjtr. issledovanija). 2013. № 7. S. 40-49.
  13. Compton A.H. The total reflection of X-ray // Philos. Mag. 1923. V. 45. P. 1121-1131.
  14. Born M., Volf EH. Osnovy optiki. M.: Nauka. 1973. 719 s.
  15. Egorov V.K., Egorov E.V. EHksperimentalnye issledovanija i model formirovanija rentgenovskikh puchkov nanorazmernogo diapazona // Poverkhnost (rentg., sinkhr., nejjtr. issledovanija). 2005. № 12. C. 24-46.
  16. Kumahov M., Komarov F. Multiple reflection from surface X-ray optics // Phys. Rep. 1990, V. 191. P. 289-352.
  17. Egorov V.K., Egorov E.V. Uslovija realizacii radiacionnojj sverkhtekuchesti i nekotorye svojjstva puchkov, sformirovannykh ploskimi rentgenovskimi volnovodami-rezonatorami // Poverkhnost (rentg., sinkhr., nejjtr. issledovanija). 2007. № 1. S. 82-99.
  18. Blokhin M.A. Fizika rentgenovskikh luchejj. M.: GITTL. 1957. 518 s.
  19. Mandel L., Volf EH. Opticheskaja kogerentnost i kvantovaja optika. M.: Fizmatlit. 2000. 895 s.
  20. Landau L.D., Lifshic E.M. EHlektrodinamika sploshnykh sred. M.: GIFML. 1959. S. 510-523.
  21. Egorov V.K., Egorov E.V. Composite X-ray waveguide-resonator as a background for the new generation of the material testing equipment for films on Si substrate // Mat. Res. Soc. Symp. Proc. 2002. V. 716. R. 189-195.
  22. Egorov V.K., Egorov E.V. Osobennosti rentgenovskojj nanofotoniki v uslovijakh vozdejjstvija opticheskogo izluchenija // «Poluprovodniki-2015» / Materialy 12-jj Ross. konf. po poluprovodnikam (21-25 sentjabrja 2015 g., Ershovo). M. 2015.S. 358.
  23. Egorov V.K., Egorov E.V. Peculiarities of the planar waveguide-resonator application for TXRF spectrometry, Review // Advances in X-ray Chem. Anal. Japan. 2013. V. 44.R. 21-40.