Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>

Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>

The influence of isovalent impurity of Si on the kinetics of electron processes in n-Ge <Sb> single crystals has been investigated. It has been shown that in the region of predominant impurity scattering (at Т = 77.4 K), the presence of isovalent impurity significantly reduces the mobility...

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Datum:2014
1. Verfasser: Gaidar, G.P.
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Veröffentlicht: Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 2014
Schriftenreihe:Semiconductor Physics Quantum Electronics & Optoelectronics
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spelling nasplib_isofts_kiev_ua-123456789-1183552025-02-23T18:08:29Z Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb> Gaidar, G.P. The influence of isovalent impurity of Si on the kinetics of electron processes in n-Ge <Sb> single crystals has been investigated. It has been shown that in the region of predominant impurity scattering (at Т = 77.4 K), the presence of isovalent impurity significantly reduces the mobility of charge carriers and changes the sign of inequality ne₃₀₀k / ne₇₇.₄k > 1 characteristic of n-Ge <Sb> single crystals to the opposite one. It has found that in n-Ge <Sb> samples irradiated by y-rays (⁶⁰Co) with the dose 1.23*10⁸ R, the charge carrier mobility has low radiation stability and decreases with increasing the magnetic field, while remaining practically unchanged in the region of the intermediate Н values. 2014 Article Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb> / G.P. Gaidar // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2014. — Т. 17, № 1. — С. 25-28. — Бібліогр.: 14 назв. — англ. 1560-8034 PACS 61.82.Fk, 61.72.uf, 61.72.S-, 72.20.-i https://nasplib.isofts.kiev.ua/handle/123456789/118355 en Semiconductor Physics Quantum Electronics & Optoelectronics application/pdf Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description The influence of isovalent impurity of Si on the kinetics of electron processes in n-Ge <Sb> single crystals has been investigated. It has been shown that in the region of predominant impurity scattering (at Т = 77.4 K), the presence of isovalent impurity significantly reduces the mobility of charge carriers and changes the sign of inequality ne₃₀₀k / ne₇₇.₄k > 1 characteristic of n-Ge <Sb> single crystals to the opposite one. It has found that in n-Ge <Sb> samples irradiated by y-rays (⁶⁰Co) with the dose 1.23*10⁸ R, the charge carrier mobility has low radiation stability and decreases with increasing the magnetic field, while remaining practically unchanged in the region of the intermediate Н values.
format Article
author Gaidar, G.P.
spellingShingle Gaidar, G.P.
Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>
Semiconductor Physics Quantum Electronics & Optoelectronics
author_facet Gaidar, G.P.
author_sort Gaidar, G.P.
title Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>
title_short Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>
title_full Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>
title_fullStr Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>
title_full_unstemmed Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb>
title_sort investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰co) on electrophysical parameters of n-ge <sb>
publisher Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
publishDate 2014
url https://nasplib.isofts.kiev.ua/handle/123456789/118355
citation_txt Investigation of the influence of isovalent impurity of silicon and y-irradiation (⁶⁰Co) on electrophysical parameters of n-Ge <Sb> / G.P. Gaidar // Semiconductor Physics Quantum Electronics & Optoelectronics. — 2014. — Т. 17, № 1. — С. 25-28. — Бібліогр.: 14 назв. — англ.
series Semiconductor Physics Quantum Electronics & Optoelectronics
work_keys_str_mv AT gaidargp investigationoftheinfluenceofisovalentimpurityofsiliconandyirradiation60coonelectrophysicalparametersofngesb
first_indexed 2025-11-24T06:14:47Z
last_indexed 2025-11-24T06:14:47Z
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fulltext Semiconductor Physics, Quantum Electronics & Optoelectronics, 2014. V. 17, N 1. P. 25-28. © 2014, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 25 PACS 61.82.Fk, 61.72.uf, 61.72.S-, 72.20.-i Investigation of the influence of isovalent impurity of silicon and -irradiation (60Co) on electrophysical parameters of n-Ge Sb G.P. Gaidar Institute for Nuclear Research, National Academy of Sciences of Ukraine, 47, prospect Nauky, 03680 Kyiv, Ukraine; e-mail: gaydar@kinr.kiev.ua Abstract. The influence of isovalent impurity of Si on the kinetics of electron processes in n-Ge Sb single crystals has been investigated. It has been shown that in the region of predominant impurity scattering (at Т  77.4 K), the presence of isovalent impurity significantly reduces the mobility of charge carriers and changes the sign of inequality 1/ K4.77K300 ee nn characteristic of n-Ge Sb single crystals to the opposite one. It has found that in n-Ge Sb samples irradiated by -rays (60Co) with the dose 1.23108 R, the charge carrier mobility has low radiation stability and decreases with increasing the magnetic field, while remaining practically unchanged in the region of the intermediate Н values. Keywords: germanium, isovalent impurity, silicon, γ-irradiation, Hall effect, charge carrier mobility, electron concentration. Manuscript received 11.11.13; revised version received 26.12.13; accepted for publication 20.03.14; published online 31.03.14. 1. Introduction For most of problems of the applied character, it is important not only a high degree of homogeneity of the crystal, but what kind and state of impurity are available in its bulk, since all this, ultimately, influences the concentration of charge carriers and their mobility. These problems can be solved by investigating crystals in various aspects: a) by direct studying the influence of certain chemical elements on their electrical properties; b) by revealing features of the influence of semiconductor compensating impurities on these properties; c) by analyzing various schemes of complexing and its consequences to which it leads in the crystal bulk. Concerning electrically active impurities, at least, basic properties of almost every element leading to formation of singly and multiply charged centers in Ge and Si were studied. More difficult is the situation with the so-called electrically passive impurities of different elements in these crystals. When considering that according to the data of mass-spectroscopic analysis, the content of oxygen in Ge is about 21018 cm–3, and the contents of hydrogen and carbon in it are about the same [1], then, naturally, a question arises, what features of charge carrier scattering, for example, may be associated with these impurities, since in other experiments (e.g. when studying absorption of infrared radiation [2]), the presence of these impurities in the crystal bulk is easily singled out. The question concerning the interaction of these impurities with other impurities that are in the n- Ge crystal bulk and resulting formation of various complexes is of particular interest. For example, the impurity atoms of Si in Ge, which are isovalent impurities, may affect transport phenomena occurring in germanium not only as electrically neutral elementary scatterers, but also in the form of neutral or charged complexes. These complexes may arise during interaction of silicon atoms with the atoms of electrically neutral or active impurities that are in the crystal bulk. This fact combined with very little data in the literature Semiconductor Physics, Quantum Electronics & Optoelectronics, 2014. V. 17, N 1. P. 25-28. © 2014, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 26 Table. Electrophysical parameters of n-Ge single crystals for unitary (Ge Sb) and double doping (Ge Sb+Si). Т  300 K Т  77.4 K D op an t N um be r of n- G e sa m pl e R, сm3/Coul ne, сm-3 , сm2/Vs R, сm3/Coul ne, сm–3 , сm2/Vs K4.77 K300 e e n n r  1 5.09105 1.231014 2960 4.70105 1.331014 23100 0.925 2 3.70104 1.691014 2680 3.65104 1.761014 19600 0.960Sb+Si 3 2.86104 2.181014 3200 2.54104 2.461014 20500 0.886 1' 9.04105 6.921013 3070 1.08105 5.781013 29200 1.197 2' 8.09104 7.741013 3050 9.70104 6.901013 28300 1.122Sb 3' 6.90104 9.081013 2560 8.15104 7.681013 27000 1.182 relative to the problem of complex formation in Ge (the situation with Si containing isovalent impurity of Ge is somewhat better [3-6]) important in general for physics and chemistry of solids have prompted to undertake studying the influence of Si isovalent impurities on the Hall mobility of charge carriers in n – Ge. Back in the sufficiently early studies (see, e.g. [7]), it was shown that Si is an electrically neutral impurity relative to Ge, i.e., its atoms found in the bulk of Ge do not lead to appearance of additional charge carriers. However, it can be assumed that the impurity atoms of Si (even in the case of its electrical neutrality) influence on the mobility of charge carriers in the area of impurity scattering. The aim of this study was to experimental determine contribution of this scattering in a resultant value of the mobility. For this goal, comparative experiments using the reference samples of Ge doped with Sb and samples of Ge doped with Sb and Si were carried out. The scientific literature, as far as it is known [8-12], is very poor in sources related to the study of the kinetics of the electron gas in crystals grown at combined doping (i.e., when doping more than one impurity). 2. Results and discussion To study the influence of Si isovalent impurity on electrophysical properties of n-Ge doped with an electrically-active impurity of antimony (Sb), ingots, some of which were doped only with Sb impurity (unitary doping) and others besides the Sb impurity were doped with silicon with approximately the same concentration (double or combined doping), were used. From these ingots, two groups of samples (three samples in each group) were prepared. The obtained samples possess suitable sizes and shapes for measurements of the resistivity and Hall effect both at room temperature and at liquid nitrogen one (Fig. 1). The samples in both cases were cut from ingots in the direction of their growth, which coincided with the crystallographic orientation [110]. The magnetic field oriented in the crystallographic direction H  || [001] was applied perpendicular to the lateral surface of the samples. All the measurements were performed at H = 2340 Oe. Before soldering current contacts and contacts to the measuring probes, the samples were polished and etched for about 2 min in a boiling solution of 30 % hydrogen peroxide, and then they were washed with distilled water. After the contacts were soldered using pure tin (Sn), the samples were etched again. Before the measurements, the ohmic regime of current contacts was tested at the current values that by several times exceeded the values used in our experiments. The results of the measurements carried out using the samples of germanium both at 300 K and at 77.4 K are presented in Table. The results obtained by the experiments (Table) show that the insertion of isovalent impurity of Si in Ge crystals (even more heavily doped with antimony than the 1'–3' samples) leads to a significant change in electrophysical properties of these crystals, which finds its expression in a number of features. For example, the sign of inequality 1/ K4.77K300 ee nn , which is typical for the initial samples (i.e., for n-Ge Sb), changes to the opposite one when introducing isovalent silicon atoms into the germanium crystal in addition to doped Sb atoms. Fig. 1. External view, shape and dimensions (in millimeters) of investigated n-Ge samples. Semiconductor Physics, Quantum Electronics & Optoelectronics, 2014. V. 17, N 1. P. 25-28. © 2014, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 27 Table shows that at dominant scattering by the lattice vibrations (i.e., at 300 K), in the samples of unitary and double doping, the values of mobility 300 K are conventional for n-Ge with the concentration of charge carriers 1013…1014 cm–3 and are about 2700...3000 сm2/Vs. However, in the region of predominant impurity scattering (i.e., at 77.4 K), in the crystals of double doping (n-Ge Sb+Si), values of the charge carrier mobility 77.4 K are considerably lower than those in the samples of unitary doping. Thus, the isovalent impurity of Si atoms, being electrically passive, significantly reduces the mobility of charge carriers in Ge crystals, doped with electrically active impurity of Sb as a consequence of manifestation of the additional scattering of charge carriers by neutral centers [13]. This result may be caused by some difference in the tetrahedral radii of Si and Ge (rSi = 1.17 Å; rGe = 1.22 Å) and, therefore, the emergence of local internal stresses of the lattice around Si atoms. It can also be a manifestation of imperfections of the Ge lattice doped with Si, which is caused, in turn, by non- uniformity in distribution of Si impurity in the bulk of the studied crystals. The values of the mobility of charge carriers in the samples of double doping were not only smaller than the values 77.4 K, typical for samples of unitary doping, but they were also less sensitive (by approximately 1.3 times) to the concentration of dopant in the bulk of the samples. This is clear from the fact that, at the temperature 77.4 K, an increase of the concentration of dopant ne in n-Ge Sb crystals by 33 % results in a decrease of the charge carrier mobility in these crystals by 8 %, while in the crystals of double doping (n- Ge Sb+Si), an increase of the concentration of electrically active impurity almost twice (or, more precisely, by 85 %) provides a reduce of the mobility only by 13 %. 0 2 4 6 8 10 12 14 16 18 20 22 24 0.7 0.8 0.9 1.0 1.1 H, kOe T  T  R H / R 0 1 2 3 4 Fig. 2. Dependences RH/R0 = f(H) obtained in the experiments with n-Ge crystals doped with Si at Т  300 K (curves 1 and 2) and at Т  77.4 K (curves 3 and 4). Curves 1 and 3 for the sample 2 ( 300 K = 11.8 Ohmcm), curves 2 and 4 for the sample 3 ( 300 K = 7.6 Ohmcm) (see Table). 103 104 105 10000 15000 20000 25000 H, Oe  , с m 2 /V s 1 2 Fig. 3. Dependences  =  (Н) of n-Ge Sb crystals before (1) and after (2) -irradiation (60Со) with the dose 1.23108 R. The current and the magnetic field were directed as follows: J  || [110], H  || [001]. The fact that well-known literature lacks data on the dependence of the Hall coefficient on the magnetic field value in Ge doped with Si causes not only a technical difficulty in the processing of Hall data, but also a substantial obstacle in obtaining unambiguous results for the Hall mobility of charge carriers in these crystals. In relation with it, the measurements of the dependence of the Hall coefficient on the magnetic field value in Ge samples doped with Sb and Si were carried out. The results of these experiments fulfilled both at room temperature and at 77.4 K (Fig. 2), in fact, are typical for n-Ge (free from the Si impurities), which was studied in similar conditions [14]. In samples prepared from the ingot of unitary doping n-Ge Sb (with antimony impurity doped in melt NSb = ne = 1.21014 cm–3), in which the concentration of atomically dispersed oxygen (determined by IR- absorption spectra) was 1.21017 cm–3, the study of the dependence of Hall mobility on the magnetic field value before (initial three samples) and after -irradiation (60Co) with the dose 1.23108 R was carried out. The vectors of the current J  and magnetic field H  in the samples were directed as follows: J  || [110], H  || [001]. The dependences of the mobility of charge carriers on the magnetic field intensity in n-Ge Sb crystals before and after -irradiation are presented in Fig. 3. Fig. 3 shows that the mobility under the influence of -irradiation significantly changed only in weak and strong magnetic fields H, while in the intermediate fields this parameter (with respect to the used dose) was almost unchanged. However, the decrease in the carrier mobility with increasing the magnetic field in the samples before and after -irradiation had progressive character. Thus, from the results of our measurements, it can be concluded that in the initial samples Ge Sb of n-type with atomically dispersed (electrically neutral) oxygen impurity, the mobility of charge carriers has low radiation resistance (mobility  decreases under the influence of γ-irradiation). Semiconductor Physics, Quantum Electronics & Optoelectronics, 2014. V. 17, N 1. P. 25-28. © 2014, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 28 3. Conclusions In this paper, the influence of Si isovalent impurity on the Hall effect and electrical conduction in n-Ge single crystals doped with electrically active impurity of Sb has been investigated. It has been shown that mainly in the field of impurity scattering (at Т  77.4 K), the presence of electrically passive impurity of silicon in the germanium bulk significantly reduces the mobility of charge carriers, which is, probably, the result of a manifestation of both additional carrier scattering by neutral centers and changes in scattering caused by lattice vibrations owing to violation of its structure as a result of some difference in the covalent radii of matrix atoms (Ge) and isovalent impurity (Si). It has been found that in the crystals of double doping (n-Ge Sb+Si), the sign of inequality 1/ K4.77K300 ee nn characteristic of n-Ge Sb single crystal changes to the opposite one. It has been found that in the unitary doped n- Ge Sb samples irradiated by γ-quanta (60Со) with the dose 1.23108 R, the mobility of charge carriers has low radiation stability, and it decreases with increasing the magnetic field value. The changes are more significant in weak and strong magnetic fields H, while for the intermediate H values this parameter remains practically unchanged. References 1. B.I. Boltaks, Diffusion and Point Defects in Semiconductors. Nauka, Leningrad, 1972 (in Russian). 2. А.А. Groza, P.G. Litovchenko, М.І. Starchik, The Effects of Radiation in the Infrared Absorption and Structure of Silicon. Naukova Dumka, Kiev, 2006 (in Ukrainian). 3. L.I. Khirunenko, V.I. Shakhovtsov, V.V. Shumov, The radiation defect formation in Ge-doped silicon under low-temperature irradiation // Fizika i tekhnika poluprovodnikov, 32 (2), p. 132-134 (1998) (in Russian). 4. C.V. Budtz-Jorgensen, P. Kringhoj, A.N. Larsen, N.V. Abrosimov, Deep-level transient spectroscopy of the Ge-vacancy pair in Ge-doped n-type silicon // Phys. Rev. B, 58 (3), р. 1110-1113 (1998). 5. Yu.V. Pomozov, M.G. Sosnin, L.I. Khirunenko, V.I. Yashnik, N.V. Abrosimov, W. Shroder, M. Hohne, Oxygen-related radiation defects in Si1–xGex // Fizika i tekhnika poluprovodnikov 34 (9), p. 1030-1034 (2000), in Russian. 6. L.I. Khirunenko, V.I. Shakhovtsov, V.K. Shinkarenko, L.I. Shpinar, I.I. Yaskovets, Characteristic properties of radiation-induced defect formation in crystals SiGe // Fizika i tekhnika polu- provodnikov, 21 (3), p. 562-565 (1987), in Russian. 7. N.A. Gopiunova, Chemistry of Diamond-like Semiconductors. Leningrad. University Publ., Leningrad, 1963 (in Russian). 8. Physico-chemical Properties of Semiconductor Materials. Reference book. Ed. by A.V. Novoselova and V.B. Lazarev. Nauka, Moscow, 1979 (in Russian). 9. P.I. Baranskii, V.P. Klochkov, I.V. Potykevich, Semiconductor Electronics. (The material properties.) Reference book. Naukova Dumka, Kiev, 1975 (in Russian). 10. Z.Yu. Gotra, The Technology of Microelectronic Devices. Radio i Svyaz’, Moscow, 1991 (in Russian). 11. Solid State Physics. Encyclopaedia. (in 2 Volumes). Ed. by V.G. Baryakhtar and V.L. Vinetskii. Naukova Dumka, Kiev, Vol. I, 1996; Vol. II, 1998 (in Russian). 12. S.V. Lienkov, О.І. Lykov, V.А. Mokritskii, V.V. Zubariev, Optoelectronics of Infrared Range: Materials, Devices, Systems. TsUPL “Poligraf”. Odessa, 2005 (in Ukrainian). 13. M.S. Sodha, P.C. Eastman, Effect of neutral impurities on mobility in nondegenerate semi- conductors // Phys. Rev. 108 (6), p. 1373-1375 (1957). 14. P.I. Baransky, P.М. Kurilo, The Hall effect investigations of symmetry properties of isoenergetic surfaces in p-Ge // Fizika tverdogo tela, 6 (1), p. 54-57 (1964), in Russian. Semiconductor Physics, Quantum Electronics & Optoelectronics, 2014. V. 17, N 1. P. 25-28. PACS 61.82.Fk, 61.72.uf, 61.72.S-, 72.20.-i Investigation of the influence of isovalent impurity of silicon and (-irradiation (60Co) on electrophysical parameters of n-Ge (Sb( G.P. Gaidar Institute for Nuclear Research, National Academy of Sciences of Ukraine, 47, prospect Nauky, 03680 Kyiv, Ukraine; e-mail: gaydar@kinr.kiev.ua Abstract. The influence of isovalent impurity of Si on the kinetics of electron processes in n-Ge (Sb( single crystals has been investigated. It has been shown that in the region of predominant impurity scattering (at Т ( 77.4 K), the presence of isovalent impurity significantly reduces the mobility of charge carriers and changes the sign of inequality 1 / K 4 . 77 K 300 > e e n n characteristic of n-Ge (Sb( single crystals to the opposite one. It has found that in n-Ge (Sb( samples irradiated by (-rays (60Co) with the dose 1.23(108 R, the charge carrier mobility has low radiation stability and decreases with increasing the magnetic field, while remaining practically unchanged in the region of the intermediate Н values. Keywords: germanium, isovalent impurity, silicon, γ-irradiation, Hall effect, charge carrier mobility, electron concentration. Manuscript received 11.11.13; revised version received 26.12.13; accepted for publication 20.03.14; published online 31.03.14. 1. Introduction For most of problems of the applied character, it is important not only a high degree of homogeneity of the crystal, but what kind and state of impurity are available in its bulk, since all this, ultimately, influences the concentration of charge carriers and their mobility. These problems can be solved by investigating crystals in various aspects: a) by direct studying the influence of certain chemical elements on their electrical properties; b) by revealing features of the influence of semiconductor compensating impurities on these properties; c) by analyzing various schemes of complexing and its consequences to which it leads in the crystal bulk. Concerning electrically active impurities, at least, basic properties of almost every element leading to formation of singly and multiply charged centers in Ge and Si were studied. More difficult is the situation with the so-called electrically passive impurities of different elements in these crystals. When considering that according to the data of mass-spectroscopic analysis, the content of oxygen in Ge is about 2(1018 cm–3, and the contents of hydrogen and carbon in it are about the same [1], then, naturally, a question arises, what features of charge carrier scattering, for example, may be associated with these impurities, since in other experiments (e.g. when studying absorption of infrared radiation [2]), the presence of these impurities in the crystal bulk is easily singled out. The question concerning the interaction of these impurities with other impurities that are in the n-Ge crystal bulk and resulting formation of various complexes is of particular interest. For example, the impurity atoms of Si in Ge, which are isovalent impurities, may affect transport phenomena occurring in germanium not only as electrically neutral elementary scatterers, but also in the form of neutral or charged complexes. These complexes may arise during interaction of silicon atoms with the atoms of electrically neutral or active impurities that are in the crystal bulk. This fact combined with very little data in the literature relative to the problem of complex formation in Ge (the situation with Si containing isovalent impurity of Ge is somewhat better [3-6]) important in general for physics and chemistry of solids have prompted to undertake studying the influence of Si isovalent impurities on the Hall mobility of charge carriers in n – Ge. K 4 . 77 K 300 e e n n r = Back in the sufficiently early studies (see, e.g. [7]), it was shown that Si is an electrically neutral impurity relative to Ge, i.e., its atoms found in the bulk of Ge do not lead to appearance of additional charge carriers. However, it can be assumed that the impurity atoms of Si (even in the case of its electrical neutrality) influence on the mobility of charge carriers in the area of impurity scattering. The aim of this study was to experimental determine contribution of this scattering in a resultant value of the mobility. For this goal, comparative experiments using the reference samples of Ge doped with Sb and samples of Ge doped with Sb and Si were carried out. The scientific literature, as far as it is known [8-12], is very poor in sources related to the study of the kinetics of the electron gas in crystals grown at combined doping (i.e., when doping more than one impurity). 2. Results and discussion To study the influence of Si isovalent impurity on electrophysical properties of n-Ge doped with an electrically-active impurity of antimony (Sb), ingots, some of which were doped only with Sb impurity (unitary doping) and others besides the Sb impurity were doped with silicon with approximately the same concentration (double or combined doping), were used. From these ingots, two groups of samples (three samples in each group) were prepared. The obtained samples possess suitable sizes and shapes for measurements of the resistivity and Hall effect both at room temperature and at liquid nitrogen one (Fig. 1). The samples in both cases were cut from ingots in the direction of their growth, which coincided with the crystallographic orientation [110]. The magnetic field oriented in the crystallographic direction H r || [001] was applied perpendicular to the lateral surface of the samples. All the measurements were performed at H = 2340 Oe. Before soldering current contacts and contacts to the measuring probes, the samples were polished and etched for about 2 min in a boiling solution of 30 % hydrogen peroxide, and then they were washed with distilled water. After the contacts were soldered using pure tin (Sn), the samples were etched again. Before the measurements, the ohmic regime of current contacts was tested at the current values that by several times exceeded the values used in our experiments. The results of the measurements carried out using the samples of germanium both at 300 K and at 77.4 K are presented in Table. The results obtained by the experiments (Table) show that the insertion of isovalent impurity of Si in Ge crystals (even more heavily doped with antimony than the 1'–3' samples) leads to a significant change in electrophysical properties of these crystals, which finds its expression in a number of features. For example, the sign of inequality 1 / K 4 . 77 K 300 > e e n n , which is typical for the initial samples (i.e., for n-Ge (Sb(), changes to the opposite one when introducing isovalent silicon atoms into the germanium crystal in addition to doped Sb atoms. Fig. 1. External view, shape and dimensions (in millimeters) of investigated n-Ge samples. Table shows that at dominant scattering by the lattice vibrations (i.e., at 300 K), in the samples of unitary and double doping, the values of mobility (300 K are conventional for n-Ge with the concentration of charge carriers 1013…1014 cm–3 and are about 2700...3000 сm2/V(s. However, in the region of predominant impurity scattering (i.e., at 77.4 K), in the crystals of double doping (n-Ge (Sb+Si(), values of the charge carrier mobility (77.4 K are considerably lower than those in the samples of unitary doping. Thus, the isovalent impurity of Si atoms, being electrically passive, significantly reduces the mobility of charge carriers in Ge crystals, doped with electrically active impurity of Sb as a consequence of manifestation of the additional scattering of charge carriers by neutral centers [13]. This result may be caused by some difference in the tetrahedral radii of Si and Ge (rSi = 1.17 Å; rGe = 1.22 Å) and, therefore, the emergence of local internal stresses of the lattice around Si atoms. It can also be a manifestation of imperfections of the Ge lattice doped with Si, which is caused, in turn, by non-uniformity in distribution of Si impurity in the bulk of the studied crystals. The values of the mobility of charge carriers in the samples of double doping were not only smaller than the values (77.4 K, typical for samples of unitary doping, but they were also less sensitive (by approximately 1.3 times) to the concentration of dopant in the bulk of the samples. This is clear from the fact that, at the temperature 77.4 K, an increase of the concentration of dopant ne in n-Ge (Sb( crystals by 33 % results in a decrease of the charge carrier mobility in these crystals by 8 %, while in the crystals of double doping (n-Ge (Sb+Si(), an increase of the concentration of electrically active impurity almost twice (or, more precisely, by 85 %) provides a reduce of the mobility only by 13 %. 0 2 4 6 8 10 12 14 16 18 20 22 24 0.7 0.8 0.9 1.0 1.1 H , kOe T » 77.4 K T » 300 K R H / R 0 1 2 3 4 Fig. 2. Dependences RH/R0 = f(H) obtained in the experiments with n-Ge crystals doped with Si at Т ( 300 K (curves 1 and 2) and at Т ( 77.4 K (curves 3 and 4). Curves 1 and 3 for the sample 2 (( 300 K = 11.8 Ohm(cm), curves 2 and 4 for the sample 3 (( 300 K = 7.6 Ohm(cm) (see Table). 10 3 10 4 10 5 10000 15000 20000 25000 H , Oe m , сm 2 /V × s 1 2 Fig. 3. Dependences ( = ( (Н) of n-Ge (Sb( crystals before (1) and after (2) (-irradiation (60Со) with the dose 1.23(108 R. The current and the magnetic field were directed as follows: J r || [110], H r || [001]. The fact that well-known literature lacks data on the dependence of the Hall coefficient on the magnetic field value in Ge doped with Si causes not only a technical difficulty in the processing of Hall data, but also a substantial obstacle in obtaining unambiguous results for the Hall mobility of charge carriers in these crystals. In relation with it, the measurements of the dependence of the Hall coefficient on the magnetic field value in Ge samples doped with Sb and Si were carried out. The results of these experiments fulfilled both at room temperature and at 77.4 K (Fig. 2), in fact, are typical for n-Ge (free from the Si impurities), which was studied in similar conditions [14]. In samples prepared from the ingot of unitary doping n-Ge (Sb( (with antimony impurity doped in melt NSb = ne = 1.2(1014 cm–3), in which the concentration of atomically dispersed oxygen (determined by IR-absorption spectra) was (1.2(1017 cm–3, the study of the dependence of Hall mobility on the magnetic field value before (initial three samples) and after (-irradiation (60Co) with the dose 1.23(108 R was carried out. The vectors of the current J r and magnetic field H r in the samples were directed as follows: J r || [110], H r || [001]. The dependences of the mobility of charge carriers on the magnetic field intensity in n-Ge (Sb( crystals before and after (-irradiation are presented in Fig. 3. Fig. 3 shows that the mobility under the influence of (-irradiation significantly changed only in weak and strong magnetic fields H, while in the intermediate fields this parameter (with respect to the used dose) was almost unchanged. However, the decrease in the carrier mobility with increasing the magnetic field in the samples before and after (-irradiation had progressive character. Thus, from the results of our measurements, it can be concluded that in the initial samples Ge (Sb( of n-type with atomically dispersed (electrically neutral) oxygen impurity, the mobility of charge carriers has low radiation resistance (mobility ( decreases under the influence of γ-irradiation). 3. Conclusions In this paper, the influence of Si isovalent impurity on the Hall effect and electrical conduction in n-Ge single crystals doped with electrically active impurity of Sb has been investigated. It has been shown that mainly in the field of impurity scattering (at Т ( 77.4 K), the presence of electrically passive impurity of silicon in the germanium bulk significantly reduces the mobility of charge carriers, which is, probably, the result of a manifestation of both additional carrier scattering by neutral centers and changes in scattering caused by lattice vibrations owing to violation of its structure as a result of some difference in the covalent radii of matrix atoms (Ge) and isovalent impurity (Si). It has been found that in the crystals of double doping (n-Ge (Sb+Si(), the sign of inequality 1 / K 4 . 77 K 300 > e e n n characteristic of n-Ge (Sb( single crystal changes to the opposite one. It has been found that in the unitary doped n-Ge (Sb( samples irradiated by γ-quanta (60Со) with the dose 1.23(108 R, the mobility of charge carriers has low radiation stability, and it decreases with increasing the magnetic field value. The changes are more significant in weak and strong magnetic fields H, while for the intermediate H values this parameter remains practically unchanged. References 1. B.I. Boltaks, Diffusion and Point Defects in Semiconductors. Nauka, Leningrad, 1972 (in Russian). 2. А.А. Groza, P.G. Litovchenko, М.І. Starchik, The Effects of Radiation in the Infrared Absorption and Structure of Silicon. Naukova Dumka, Kiev, 2006 (in Ukrainian). 3. L.I. Khirunenko, V.I. Shakhovtsov, V.V. Shumov, The radiation defect formation in Ge-doped silicon under low-temperature irradiation // Fizika i tekhnika poluprovodnikov, 32 (2), p. 132-134 (1998) (in Russian). 4. C.V. Budtz-Jorgensen, P. Kringhoj, A.N. Larsen, N.V. Abrosimov, Deep-level transient spectroscopy of the Ge-vacancy pair in Ge-doped n-type silicon // Phys. Rev. B, 58 (3), р. 1110-1113 (1998). 5. Yu.V. Pomozov, M.G. Sosnin, L.I. Khirunenko, V.I. Yashnik, N.V. Abrosimov, W. Shroder, M. Hohne, Oxygen-related radiation defects in Si1–xGex // Fizika i tekhnika poluprovodnikov 34 (9), p. 1030-1034 (2000), in Russian. 6. L.I. Khirunenko, V.I. Shakhovtsov, V.K. Shinkarenko, L.I. Shpinar, I.I. Yaskovets, Characteristic properties of radiation-induced defect formation in crystals Si(Ge( // Fizika i tekhnika polu​provodnikov, 21 (3), p. 562-565 (1987), in Russian. 7. N.A. Gopiunova, Chemistry of Diamond-like Semiconductors. Leningrad. University Publ., Leningrad, 1963 (in Russian). 8. Physico-chemical Properties of Semiconductor Materials. Reference book. Ed. by A.V. Novoselova and V.B. Lazarev. Nauka, Moscow, 1979 (in Russian). 9. P.I. Baranskii, V.P. Klochkov, I.V. Potykevich, Semiconductor Electronics. (The material properties.) Reference book. Naukova Dumka, Kiev, 1975 (in Russian). 10. Z.Yu. Gotra, The Technology of Microelectronic Devices. Radio i Svyaz’, Moscow, 1991 (in Russian). 11. Solid State Physics. Encyclopaedia. (in 2 Volumes). Ed. by V.G. Baryakhtar and V.L. Vinetskii. Naukova Dumka, Kiev, Vol. I, 1996; Vol. II, 1998 (in Russian). 12. S.V. Lienkov, О.І. Lykov, V.А. Mokritskii, V.V. Zubariev, Optoelectronics of Infrared Range: Materials, Devices, Systems. TsUPL “Poligraf”. Odessa, 2005 (in Ukrainian). 13. M.S. Sodha, P.C. Eastman, Effect of neutral impurities on mobility in nondegenerate semi​conductors // Phys. Rev. 108 (6), p. 1373-1375 (1957). 14. P.I. Baransky, P.М. Kurilo, The Hall effect investigations of symmetry properties of isoenergetic surfaces in p-Ge // Fizika tverdogo tela, 6 (1), p. 54-57 (1964), in Russian. Table. Electrophysical parameters of n-Ge single crystals for unitary (Ge (Sb() and double doping (Ge (Sb+Si(). Dopant� Number of n-Ge sample� Т ( 300 K� Т ( 77.4 K� � EMBED Equation.3 ���� � � � R, сm3/Coul� ne, сm�3� (, сm2/V(s� R, сm3/Coul� ne, сm–3� (, сm2/V(s� � � Sb+Si� 1� 5.09(105� 1.23(1014� 2960� 4.70(105� 1.33(1014� 23100� 0.925� � � 2� 3.70(104� 1.69(1014� 2680� 3.65(104� 1.76(1014� 19600� 0.960� � � 3� 2.86(104� 2.18(1014� 3200� 2.54(104� 2.46(1014� 20500� 0.886� � Sb� 1'� 9.04(105� 6.92(1013� 3070� 1.08(105� 5.78(1013� 29200� 1.197� � � 2'� 8.09(104� 7.74(1013� 3050� 9.70(104� 6.90(1013� 28300� 1.122� � � 3'� 6.90(104� 9.08(1013� 2560� 8.15(104� 7.68(1013� 27000� 1.182� � © 2014, V. Lashkaryov Institute of Semiconductor Physics, National Academy of Sciences of Ukraine 25 _1452415253.unknown _1452416364.unknown _1452416365.unknown _1452415262.unknown _1452415276.unknown _1452415258.unknown _1452415107.unknown _1452415174.unknown _1451131778.unknown _1452414847.unknown _1451129645.unknown

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