Influence of fast neutron irradiation on the phase composition and optical properties of homogeneous SiOx and composite Si–SiOx thin films
Layers and devices utilizing semiconductor nanocrystals have been the subjects of intensive research due to applications in opto- and microelectronic devices, solar cells, detectors, memories and in many more fields. We have shown previously that those nanocrystals in dielectric matrices undergo a s...
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| Published in | Journal of materials science Vol. 56; no. 4; pp. 3197 - 3209 |
|---|---|
| Main Authors | , , , , , , , , |
| Format | Journal Article |
| Language | English |
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Springer US
01.02.2021
Springer Nature B.V |
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| Abstract | Layers and devices utilizing semiconductor nanocrystals have been the subjects of intensive research due to applications in opto- and microelectronic devices, solar cells, detectors, memories and in many more fields. We have shown previously that those nanocrystals in dielectric matrices undergo a substantial reformation during electron irradiation. The research of the interaction between semiconductor nanoclusters and irradiation is important for both the intentional modification of the structures and for understanding the stability of those devices under harsh, radiative conditions (e.g. space, nuclear, medical diagnosis, or similar applications). In the present research, we investigated the influence of neutron irradiation on substoichiometric silicon oxide. We investigated both homogeneous case and inhomogeneous case of matrices with silicon nanoclusters. We found that a fast neutron flux of 5.5 × 10
13
neutrons/cm
2
s and a fluence of 3.96 × 10
17
neutrons/cm
2
induce phase separation in the homogeneous films, whereas it decreases the volume fraction of the amorphous silicon phase caused by the reducing size of amorphous nanoclusters in the inhomogeneous films. |
|---|---|
| AbstractList | Layers and devices utilizing semiconductor nanocrystals have been the subjects of intensive research due to applications in opto- and microelectronic devices, solar cells, detectors, memories and in many more fields. We have shown previously that those nanocrystals in dielectric matrices undergo a substantial reformation during electron irradiation. The research of the interaction between semiconductor nanoclusters and irradiation is important for both the intentional modification of the structures and for understanding the stability of those devices under harsh, radiative conditions (e.g. space, nuclear, medical diagnosis, or similar applications). In the present research, we investigated the influence of neutron irradiation on substoichiometric silicon oxide. We investigated both homogeneous case and inhomogeneous case of matrices with silicon nanoclusters. We found that a fast neutron flux of 5.5 × 10
13
neutrons/cm
2
s and a fluence of 3.96 × 10
17
neutrons/cm
2
induce phase separation in the homogeneous films, whereas it decreases the volume fraction of the amorphous silicon phase caused by the reducing size of amorphous nanoclusters in the inhomogeneous films. Layers and devices utilizing semiconductor nanocrystals have been the subjects of intensive research due to applications in opto- and microelectronic devices, solar cells, detectors, memories and in many more fields. We have shown previously that those nanocrystals in dielectric matrices undergo a substantial reformation during electron irradiation. The research of the interaction between semiconductor nanoclusters and irradiation is important for both the intentional modification of the structures and for understanding the stability of those devices under harsh, radiative conditions (e.g. space, nuclear, medical diagnosis, or similar applications). In the present research, we investigated the influence of neutron irradiation on substoichiometric silicon oxide. We investigated both homogeneous case and inhomogeneous case of matrices with silicon nanoclusters. We found that a fast neutron flux of 5.5 × 1013 neutrons/cm2 s and a fluence of 3.96 × 1017 neutrons/cm2 induce phase separation in the homogeneous films, whereas it decreases the volume fraction of the amorphous silicon phase caused by the reducing size of amorphous nanoclusters in the inhomogeneous films. Layers and devices utilizing semiconductor nanocrystals have been the subjects of intensive research due to applications in opto- and microelectronic devices, solar cells, detectors, memories and in many more fields. We have shown previously that those nanocrystals in dielectric matrices undergo a substantial reformation during electron irradiation. The research of the interaction between semiconductor nanoclusters and irradiation is important for both the intentional modification of the structures and for understanding the stability of those devices under harsh, radiative conditions (e.g. space, nuclear, medical diagnosis, or similar applications). In the present research, we investigated the influence of neutron irradiation on substoichiometric silicon oxide. We investigated both homogeneous case and inhomogeneous case of matrices with silicon nanoclusters. We found that a fast neutron flux of 5.5 × 10¹³ neutrons/cm² s and a fluence of 3.96 × 10¹⁷ neutrons/cm² induce phase separation in the homogeneous films, whereas it decreases the volume fraction of the amorphous silicon phase caused by the reducing size of amorphous nanoclusters in the inhomogeneous films. |
| Author | Bineva, Irina Valcheva, Evgenia Antonova, Krassimira Petrik, Peter Fabian, Margit Nesheva, Diana Hristova-Vasileva, Temenuga Sulyok, Attila Fogarassy, Zsolt |
| Author_xml | – sequence: 1 givenname: Diana surname: Nesheva fullname: Nesheva, Diana organization: Institute of Solid State Physics, Bulgarian Academy of Sciences – sequence: 2 givenname: Zsolt surname: Fogarassy fullname: Fogarassy, Zsolt organization: Centre for Energy Research – sequence: 3 givenname: Margit surname: Fabian fullname: Fabian, Margit organization: Centre for Energy Research – sequence: 4 givenname: Temenuga surname: Hristova-Vasileva fullname: Hristova-Vasileva, Temenuga organization: Institute of Solid State Physics, Bulgarian Academy of Sciences – sequence: 5 givenname: Attila surname: Sulyok fullname: Sulyok, Attila organization: Centre for Energy Research – sequence: 6 givenname: Irina surname: Bineva fullname: Bineva, Irina organization: Institute of Solid State Physics, Bulgarian Academy of Sciences – sequence: 7 givenname: Evgenia surname: Valcheva fullname: Valcheva, Evgenia organization: Faculty of Physics, Sofia University “St. Kliment Ohridski” – sequence: 8 givenname: Krassimira surname: Antonova fullname: Antonova, Krassimira organization: Institute of Solid State Physics, Bulgarian Academy of Sciences – sequence: 9 givenname: Peter orcidid: 0000-0002-5374-6952 surname: Petrik fullname: Petrik, Peter email: petrik@mfa.kfki.hu organization: Centre for Energy Research |
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| CitedBy_id | crossref_primary_10_1038_s41598_021_00336_0 crossref_primary_10_1021_acsomega_3c00486 crossref_primary_10_1016_j_jnoncrysol_2024_123342 |
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ISBN: 978-0-08-046325-4 CurielMANedevNNeshevaDSoaresJHaaschRSardelaMValdezBSankaranBManolovEBinevaIPetrovIMicrostructural characterization of thin SiOx films obtained by physical vapor depositionMat Sci Eng B20101741321361:CAS:528:DC%2BC3cXhtFCkt7nM NiZZhouSZhaoSPengWYangDPiXSilicon nanocrystals: unfading silicon materials for optoelectronicsMater Sci Eng R201913885117 HossainSMAnopchenkoAPreziosoSFerraioliLPavesiLPuckerGBelluttiPBinettiSAcciarriMSubband gap photoresponse of nanocrystalline silicon in a metal-oxide-semiconductor deviceJ Appl Phys2008104074917 KolariKVehmasTSvenskOTörmäPAaltoTSmoothing of microfabricated silicon features by thermal annealing in reducing or inert atmospheresPhys Scr.20102010014017 NeshevaDPetrikPHristova-VasilevaTFogarassyZKalasBŠćepanovićMKaschievaSDmitrievSNAntonovaKChanges in composite nc-Si-SiO2 thin films caused by 20 MeV electron irradiationNucl Instrum Methods Phys Res Sect B20194581591631:CAS:528:DC%2BC1MXhtVersLfO CurielMNede P Petrik (5338_CR57) 2008; 205 K Araki (5338_CR45) 2014; 4 I Bineva (5338_CR55) 2007; 126 5338_CR30 E Manolov (5338_CR46) 2019; 1186 Z Yu (5338_CR14) 2009; 95 AA Ischenko (5338_CR54) 2015 PE Acosta-Alba (5338_CR44) 2014; 115 T Hristova-Vasileva (5338_CR52) 2018; 123 V Donchev (5338_CR31) 2012; 520 D Nesheva (5338_CR28) 2002; 92 DV Tsu (5338_CR50) 1989; 40 D Nesheva (5338_CR53) 2008; 23 Z Ni (5338_CR3) 2019; 138 A Aktag (5338_CR9) 2010; 268 D Mateos (5338_CR33) 2013; 51 D Amans (5338_CR37) 2003; 93 D Salazar (5338_CR58) 2016; 6 E Huseynov (5338_CR24) 2016; 5 5338_CR1 JA Luna-López (5338_CR42) 2009; 27 K Awazu (5338_CR22) 2003; 94 R Behrisch (5338_CR48) 1982; 108–109 5338_CR41 A Evtukh (5338_CR40) 2015 J-M Shieh (5338_CR13) 2007; 90 MA Curiel (5338_CR29) 2010; 174 5338_CR8 GR Odette (5338_CR20) 2008; 38 B Vincent Crist (5338_CR35) 2000 5338_CR6 D Nesheva (5338_CR59) 2019; 458 H Spieler (5338_CR19) 1997; 390 AA Gismatulin (5338_CR7) 2019; 114 N Nedev (5338_CR10) 2012; 10 P Petrik (5338_CR56) 2002; 92 F Xiong (5338_CR60) 2020; 182 L Szentmiklosi (5338_CR34) 2016; 309 D Mateos (5338_CR32) 2013; 2013 M Curiel (5338_CR47) 2019; 19 M Greben (5338_CR2) 2017; 122 D Nesheva (5338_CR27) 2003; 68 5338_CR51 SM Hossain (5338_CR15) 2008; 104 G Conibeer (5338_CR4) 2012; 15 M Curiel (5338_CR39) 2010; 664 A Garibli (5338_CR26) 2019; 33 YE Bang-jiao (5338_CR49) 1999; 16 Sh Levy (5338_CR25) 2011; 1 5338_CR18 M León (5338_CR23) 2014; 61 5338_CR17 D Nesheva (5338_CR11) 2015; 13 X Liu (5338_CR21) 2017; 138 M Schnabel (5338_CR5) 2015; 212 T Lohner (5338_CR38) 2009; 11 AS Ferlauto (5338_CR36) 2002; 92 A Slav (5338_CR12) 2019; 30 M Curiel (5338_CR16) 2019; 19 K Kolari (5338_CR43) 2010; 2010 |
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| Snippet | Layers and devices utilizing semiconductor nanocrystals have been the subjects of intensive research due to applications in opto- and microelectronic devices,... |
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| SubjectTerms | Amorphous silicon Characterization and Evaluation of Materials Chemistry and Materials Science Classical Mechanics Crystallography and Scattering Methods Electron irradiation Electronic Materials Fast neutrons Fluence irradiation Materials Science Medical research Nanoclusters Nanocrystals Neutron flux Neutron irradiation Neutrons Optical properties Phase composition Phase separation Photovoltaic cells Polymer Sciences semiconductors separation silica silicon Silicon oxides Solar cells Solid Mechanics Thin films |
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| Title | Influence of fast neutron irradiation on the phase composition and optical properties of homogeneous SiOx and composite Si–SiOx thin films |
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