Characteristics of optical filters built on the basis of periodic relief reflective structures

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A scheme of a new type optical filter, built using a relief reflective periodic diffraction structure, which has a specific rectangular profile, is proposed. The input radiation beam is directed to the relief structure at a certain angle of incidence. The zero diffraction order beam is our output beam, which is separated from the other diffraction order beams with the help of a diaphragm. The incidence-reflection plane is parallel to the relief lines of the diffraction structure. The dependence of the output beam power on the angle of incidence and on the wavelength of the radiation is investigated. It is shown that the power transfer coefficient from the input to the output of the scheme substantially depends on the wavelength of the optical beam. The scheme can be used as an optical signal filter. The spectral characteristic of this type of filter has an oscillating character. The zero (minimum) values of the power transfer coefficient of radiation from the input to the output of the filter alternate with maximum values close to unity. The spectral characteristic of the filter is easy to change by changing the angle of incidence of the input beam to the relief reflecting structure. Filters of this type can be built for the ultraviolet, visible, and infrared range. Calculations of the dependence of the filter parameters on the relief depth and on the angle of incidence of the input optical beam to the relief structure are presented.

Sobre autores

Vladislav Komotskii

Peoples’ Friendship University of Russia (RUDN university)

Autor responsável pela correspondência
Email: vkomotskii@mail.ru

Professor, Doctor of Technical Sciences, Professor of Institute of Physical Research and Technology

6 Miklukho-Maklaya St., Moscow, 117198, Russian Federation

Jose Huaman

Universidad Nacional de Ingenieria

Email: jpauyac@hotmail.com

Candidate of Physical and Mathematical Sciences, Intern student of Institute of Physical Research and Technology

Av. Tupac Amaru 210 Rimac, Lima Peru

Valeriya Evstigneeva

Peoples’ Friendship University of Russia (RUDN university)

Email: evstilera@mail.ru

Student of Institute of Physical Research and Technology

6 Miklukho-Maklaya St., Moscow, 117198, Russian Federation

Bibliografia

  1. V. V. Lebedeva, Experimental optics [Eksperimental’naya optika], 3rd Edition, Publishing House of Moscow University, Moscow, 1994, in Russian.
  2. V. I. Puchkov, E. A. Iosep, G. T. Petrovsky, L. S. Iutinskaya, A. P. Ivanova, V. Smirnova, S. P. Lunkin, Coloured optical glass. Specifications [Steklo opticheskoye tsvetnoye], State Standard of the USSR, GOST 9411-91, http://docs.cntd.ru/document/gost-9411-91, 1991, in Russian.
  3. A. M. Prokhorov (Ed.), Handbook of Lasers [Spravochnik po lazeram], Vol. 2, Soviet Radio, Moscow, 1978, in Russian.
  4. I. P. Golyamin (Ed.), Ultrasound (small encyclopedia) [Ul’trazvuk (Malen’kaya entsiklopediya)], Soviet Encyclopedia, Moscow, 1979, in Russian.
  5. V. A. Komotsky, Y. M. Sokolov, N. V. Suetin, A device for filtering optical signal spectra [Ustroystvo dlya fil’tratsii spektrov opticheskogo signala], Patent for utility model 181381, in Russian (2018).
  6. V. P. Lavrintsev (Ed.), Introduction to photolithography [Vvedeniye v fotolitografiyu], Energy, Moscow, 1977, in Russian.
  7. G. V. Rosenberg, Optics of thin-layer coatings [Optika tonkosloynykh pokrytiy], State publishing house of physical and mathematical literature, Moscow, 1958, in Russian.
  8. Machine construction encyclopedia XXL [Entsiklopediya po mashinostroyeniyu XXL], in Russian. URL http://mash-xxl.info
  9. N. M. Kashchenko, Determination of the depth of the reference diffraction gratings based on the measurement and analysis of the intensities of the diffraction orders [Opredeleniye glubiny opornykh difraktsionnykh reshetok na osnove izmereniya i analiza intensivnostey difraktsionnykh poryadkov], Bulletin of the Peoples’ Friendship University of Russia. Series: Physics 7 (1) (1999) 16-27, in Russian.
  10. Gas argon laser LEXEL 85/95 (visible) [Gazovyy argonovyy lazer LEXEL 85/95 (vidimyy)], in Russian. URL http://scientific-technology.ru/laserslink/gaslaser/ lexel85ar
  11. Spectrum of a natural sunshine fluorescent light. URL https://commons.wikimedia.org/wiki/File:SpectraPhilips_32T8_natural_sunshine_fluorescent_light.svg

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