GazIn1-zPxAsySb1-x-y/InSb heterostructures for thermophotovoltaic converters

Authors

  • Lunina M.L. Federal Research Center Southern Scientific Center of the Russian Academy of Sciences, Rostov-on-Don, Russian Federation ORCID iD 0000-0002-9900-3767
  • Lunin L.S. Federal Research Center Southern Scientific Center of the Russian Academy of Sciences, Rostov-on-Don; North-Caucasian Federal University, Stavropol, Russian Federation ORCID iD 0000-0002-5534-9694
  • Pashchenko A.S. Federal Research Center Southern Scientific Center of the Russian Academy of Sciences, Rostov-on-Don; North-Caucasian Federal University, Stavropol, Russian Federation ORCID iD 0000-0002-7976-9597
  • Donskaya A.V. Platov South-Russian State Polytechnic University (NPI), Novocherkassk, Russian Federation ORCID iD 0000-0002-0548-9517
  • Stolyarov M.S. Platov South-Russian State Polytechnic University (NPI), Novocherkassk, Russian Federation ORCID iD 0009-0001-1524-4935

UDC

538.958

DOI:

https://doi.org/10.31429/vestnik-20-2-63-69

Abstract

The GaInPAsSb solid solution is used to create optoelectronic devices in the visible and IR spectral ranges. A necessary condition for increasing the efficiency of thermophotoelectric converters is a high degree of crystallographic perfection of heterostructures. However, the preparation of GaInPAsSb solid solutions is associated with a number of difficulties. It has wide areas of immiscibility, a high probability of the formation of non-stoichiometric compositions. The aim of this work is to grow GaInPAsSb/InSb heterostructures with high photoluminescent characteristics. GaInPAsSb/InSb heterostructures were grown by the method of zone recrystallization with a temperature gradient in the temperature range 753-873 K, determined from the study of liquidus temperatures. The manufacturing technique consists in the crystallization of a solution-melt of pure In, Ga, P, Sb, As components on an InSb substrate. A liquid zone with a thickness of 20-150 nm replenishment of liquid phase InPSbAs polycrystalline to create a uniform distribution of components over the thickness of the epitaxial layer. Based on the analysis of "liquid-solid" phase equilibria within the framework of the simple solution model, the technological parameters of the heteroepitaxial growth of GaInPAsSb solid solutions in the composition range 0.01x0.30, 0.01y0.45, 0.01z0.60. With an increase in the concentration of phosphorus in the solid solution, the mismatch in the lattice periods of the layer and substrate δa increases. However, the mismatch between the lattice periods of the substrate and the solid solution layer by a value of δa0.0% causes stresses at the heterointerface, which prevent spinodal decomposition, increasing the region of existence of GaInPAsSb solutions. The photoluminescence spectra of GaInAsSb/InSb and GaInPAsSb/InSb heterostructures are compared with the active region in the layer. It is shown that the addition of phosphorus to GaInAsSb leads to an increase in the intensity and a decrease in the emission bandwidth at half the height of the peaks. This indicates an improvement in the crystalline properties of the films. As a result, the use of five-component GaInPAsSb solid solutions as the active area of thermophotoelectric converters makes it possible to increase the external quantum efficiency to 0.95 in the spectral range 2700-4700 nm.

Keywords:

heterostructures, band gap, spinodal decomposition, photoluminescence, spectral characteristics

Funding information

Growth of experimental samples and calculations of spinodal decomposition were carried out within the framework of the state task of the Federal Research Center of the Southern Scientific Center of the Russian Academy of Sciences No. 122020100254-3. The spectral characteristics were measured using the resources of the North Caucasus Federal University and with the financial support of the Russian Ministry of Education and Science, unique project identifier RF-2296.61321X0029 (agreement No. 075-15-2021-687).

Author info

  • Marina L. Lunina

    канд. физ.-мат. наук, ведущий научный сотрудник лаборатории физики и технологии наногетероструктур для СВЧ-электроники и фотоники Южного научного центра РАН

  • Leonid S. Lunin

    д-р физ.-мат. наук, главный научный сотрудник, профессор лаборатории физики и технологии наногетероструктур для СВЧ-электроники и фотоники Южного научного центра РАН; главный научный сотрудник НОЦ фотовольтаики и нанотехнологий Северо-Кавказского федерального университета

  • Alexander S. Pashchenko

    канд. физ.-мат. наук, ведущий научный сотрудник лаборатории физики и технологии наногетероструктур для СВЧ-электроники и фотоники Южного научного центра РАН; старший научный сотрудник НОЦ фотовольтаики и нанотехнологий Северо-Кавказского федерального университета

  • Alina V. Donskaya

    аспирант, ассистент кафедры физики и фотоники Южно-Российского государственного политехнического университета (НПИ) им. М.И. Платова

  • Michael S. Stolyarov

    аспирант, ассистент кафедры физика и фотоника Южно-Российского государственного политехнического университета (НПИ) им. М.И. Платова

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Issue

Vol. 20 (2023) No. 2

Pages

63-69

Section

Physics

Dates

Submitted

June 13, 2023

Accepted

June 16, 2023

Published

June 30, 2023

How to Cite

[1]
Lunina, M.L., Lunin, L.S., Pashchenko, A.S., Donskaya, A.V., Stolyarov, M.S., GazIn1-zPxAsySb1-x-y/InSb heterostructures for thermophotovoltaic converters. Ecological Bulletin of Research Centers of the Black Sea Economic Cooperation, 2023, т. 20, № 2, pp. 63–69. DOI: 10.31429/vestnik-20-2-63-69

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Copyright (c) 2023 Лунина М.Л., Лунин Л.С., Пащенко А.С., Донская А.В., Столяров М.С.

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