Influence of composition of the near-surface graded-gap layer on the admittance of metal-insulator-semiconductor structures based on graded-gap MBE n-Hg₁₋xCdxTe in wide temperature range

Voitsekhovskii, A. V.; Nesmelov, S. N.; Dzyadukh, S. M.

doi:10.2478/s11772-014-0198-7

Artykuł - szczegóły

Tytuł artykułu

Influence of composition of the near-surface graded-gap layer on the admittance of metal-insulator-semiconductor structures based on graded-gap MBE n-Hg₁₋xCdxTe in wide temperature range

Autorzy

Voitsekhovskii A. V. , Nesmelov S. N. , Dzyadukh S. M.

Wybrane pełne teksty z tego czasopisma

http://journals.pan.pl/dlibra/journal/opelre

Identyfikatory

DOI

10.2478/s11772-014-0198-7

Warianty tytułu

Języki publikacji

Abstrakty

Influence of the CdTe content in a near-surface graded-gap layer on the admittance of MIS-structures fabricated on the basis of heteroepitaxial Hg₁₋xCdxTe (x = 0.22−0.23 and 0.31−0.32) films grown by molecular beam epitaxy was investigated in a wide temperature range. It is shown that a temperature drop from 77 K to 8 K results in a decrease of hysteresis of the capacitance-voltage (C−V) characteristics and a decrease of frequencies which corresponds to a high-frequency behaviour of C−V characteristics of MIS-structures based on n-HgCdTe (x = 0.22–0.23) with and without graded-gap layersand also for MIS-structures based on n-HgCdTe (x = 0.31–0.32). Temperature dependences of the resistance of the epitaxial film bulk and differential resistance of the space-charge region (SCR) in strong inversion mode were studied. The experimental results can be explained by the fact that for MIS-structures based on n-HgCdTe (x = 0.22–0.23) with the graded-gap layers and for MIS-structures based on n-HgCdTe (x = 0.31–0.32), the differential resistance of SCR is limited by Shockley-Read generation at 25–77 K. Differential resistance of SCR for MIS-structures based on n-HgCdTe (x = 0.22–0.23) without the graded-gap layers is limited by tunnelling through deep levels at 8–77 K.

Słowa kluczowe

HgCdTe MIS structure admittance graded-gap layer differential resistance of space-charge region

Wydawca

Stowarzyszenie Elektryków Polskich
Polska Akademia Nauk
Wojskowa Akademia Techniczna im. Jarosława Dąbrowskiego

Czasopismo

Opto-Electronics Review

Rocznik

2014

Tom

Vol. 22, No. 4

Strony

236--244

Opis fizyczny

Bibliogr. 25 poz., wykr.

Twórcy

autor

Voitsekhovskii A. V.

vav@elefot.tsu.ru

National Research Tomsk State University, 36 Lenina Ave., 634050 Tomsk, Russia

autor

Nesmelov S. N.

National Research Tomsk State University, 36 Lenina Ave., 634050 Tomsk, Russia

autor

Dzyadukh S. M.

National Research Tomsk State University, 36 Lenina Ave., 634050 Tomsk, Russia

Bibliografia

1. A. Rogalski, Infrared Detectors, 2nd. ed., CRC Press, Taylor & Francis Group, New York 2011.
2. J. Chu and A. Sher, Device Physics of Narrow Gap Semiconductors, Springer, New York, 2010.
3. A. Rogalski, Infrared Detectors, edited by A.V. Voitsekhovskii, Nauka, Novosibirsk, 2003. (Russian translation from English) (in Russian).
4. A.V. Voitsekhovskii and V. N. Davydov, Photoelectric MIS Structures Based on Narrow-Band Semiconductors, Radio I Svyaz’, Tomsk, 1990 (in Russian).
5. V.N. Ovsyk, G.L. Kuryshev, and Y.G. Sidorov, Matrix Photodetectors Infrared Range, Nauka, Novosibirsk, 2001 (in Russian).
6. V.S. Varavin, V.V.Vasiliev, A.V. Voitsekhovskii, and T.I. Zakhariash, “Photodiods with the low sequent resistance based on variband epitaxial layers CdxHg1–xTe”, Optical Journal 66, 69–72 (1999) (in Russian).
7. O.P. Agnihorti, C.A. Musca, and L. Faraone, “Current status and issues in the surface passivation technology of mercury cadmium telluride infrared detectors”, Semicond. Sci. Tech. 13, 839–845(1998).
8. V. Kumar, R. Pal, P.K. Chaudhury, B.L. Sharma, and V. Gopal, “A CdTe passivation process for long wavelength infrared HgCdTe photodetectors”, J. Electron. Mater. 34, 1225–1229 (2005).
9. A.V. Voitsekhovskii, S.N. Nesmelov, and S.M. Dzyadukh, “The influence of resistance of bulk of epitaxial films on capacitance-voltage characteristics of MIS-structures HgCdTe/AOF and HgCdTe/SiO2/Si3N4”, Russ. Phys. J. 48, No. 6, 584–591 (2005).
10. A.V. Voitsekhovskii, S.N. Nesmelov, S.M. Dzyadukh, V.S. Varavin, S.A. Dvoretskii, N.N. Mikhailov, Yu.G. Sidorov, and A.A. Vasil’ev, “Properties of MIS-structures based on graded-band HgCdTe grown by molecular beam epitaxy”, Semiconductors 42, 1327–1332 (2008).
11. V.N. Ovsyuk and A.V. Yartsev, “Analysis of voltage-capacitance curve of MIS-structure based on n- and p- MBE HgCdTe”, Proc. SPIE 6636, 663617 (2007).
12. V.V. Vasil’ev and Yu.P. Mashukov, “Capacitance-voltage characteristics of the p-Cd0.27Hg0.73Te-based structures with a wide-gap graded-gap surface layer”, Semiconductors 41, 37–42 (2007).
13. V.V. Vasil’ev and Yu.P. Mashukov, “Investigation of the MIS structures of the MBE CdxHg1-xTe – anodic oxide”, Applied Physics 4, 106–110 (2010) (in Russian).
14. A.A. Guzev, V.S. Varavin, S.A. Dvoretsky, A.P. Kovchavtsev, G.L. Kuryshev, I.I. Lee, Z.V. Panova, Yu.G. Sidorov, and M.V. Yakushev, “Photosensitive properties of In/ZnTe/CdTe/HgCdTe structures”, Applied Physics 2, 92–96 (2009) (in Russian).
15. M.W. Goodwin, M.A. Kinch, and R.J. Koestner, “Effects of defects on metal-insulator semiconductor properties of molecular-beam epitaxy grown HgCdTe”, J. Vac. Sci. Technol. A7, 523–527 (1989).
16. M.J. Yang, C.H. Yang, M.A. Kinch, and J.D. Beck, “Interface properties of HgCdTe metal-insulator-semiconductor capacitors”, Appl. Phys. Lett. 54, 265–267 (1989).
17. M. Zvara, R. Grill, P. Hlidek, et al. “Interface trap conductance spectroscopy of a narrow-gap Hg1–xCdxTe (x approximately = 0.2) MIS device”, Semicond. Sci. Tecnol. 10, 1145–1150 (1995).
18. M. Zvara, R. Grill, P. Hlidek, et al. “Magneto-conductance spectroscopy of a narrow-gap MIS device”, Semicond. Sci. Tecnol. 11, 1718–1724 (1996).
19. W. He and Z. Celik-Butler, “1/f noise and dark current components in HgCdTe MIS infrared detectors”, Solid-State Electron. 39, 127–132 (1996).
20. A.V. Voitsekhovskii, S.N. Nesmelov, and S.M. Dzyadukh, “Investigation into MIS structures based on gradedband-gap hetero-epitaxial HgCdTe grown by molecular-beam epitaxy using photo-emf and conductivity methods”, Russ. Phys. J. 52, 1003–1020 (2009).
21. V.I. Gaman, Physics of Semiconductor Devices, Publishing scientific and technical literature, Tomsk, 2000 (in Russian).
22. A.V. Voitsekhovskii, S.N. Nesmelov, S.M. Dzyadukh, V.S. Varavin, S.A. Dvoretskii, N.N. Mikhailov, Yu.G. Sidorov, and M.V. Yakushev, “Influence of near-surface graded-gap layers on electrical characteristics of MIS-structures based on MBE grown HgCdTe”, Opto-Electron. Rev. 18, 259–262 (2010).
23. A.V. Voitsekhovskii, S.N. Nesmelov, and S.M. Dzyadukh, “Capacitance-voltage characteristics of metal-insulator-semiconductor structures based on graded-gap HgCdTe with various insulators”, Thin Solid Films 522C, 261–266 (2012).
24. A.V. Voitsekhovskii, S.N. Nesmelov, and S.M. Dzyadukh, “Photoelectrical characteristics of metal-insulator-semiconductor structures based on graded-gap HgCdTe grown by molecular-beam epitaxy”, Thin Solid Films. 551, 92–97 (2014).
25. M.A. Kinch, “Metal-insulator-semiconductor infrared detectors”, in Semiconductors and Semimetals, Vol. 18, pp. 313–378, edited by R.K.Willardson and A.C. Beer, Academic Press, New York, 1981.

Typ dokumentu

Bibliografia

Identyfikator YADDA

bwmeta1.element.baztech-f341b23e-fc36-457b-93d3-9e760f8b5145