Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing

Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing

Structure perfection of the silicon crystals grown by the Czochralski and floating zone methods after implantation with oxygen or neon fast iones followed by annealing at the temperatures T ~ 1050-1150 ⁰0C, when large SiOx precipitates were formed, was studied by means of various X-ray diffraction m...

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Date:1999
Main Authors: Datsenko, L.I., Auleytner, J., Misiuk, A., Klad'ko, V.P., Machulin, V.F., Bak-Misiuk, J., Zymierska, D., Antonova, I.V., Melnyk, V.M., Popov, V.P., Czosnyka, T., Choinski, J.
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Language:English
Published: Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України 1999
Series:Semiconductor Physics Quantum Electronics & Optoelectronics
Online Access:https://nasplib.isofts.kiev.ua/handle/123456789/117934
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Cite this:Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing / L.I. Datsenko, J. Auleytner, A. Misiuk, V.P. Klad'ko, V.F. Machulin, J. Bak-Misiuk, D. Zymierska, I.V. Antonova, V.M. Melnyk, V.P. Popov, T. Czosnyka, J. Choinski // Semiconductor Physics Quantum Electronics & Optoelectronics. — 1999. — Т. 2, № 1. — С. 56-61. — Бібліогр.: 9 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1179342025-02-09T15:49:56Z Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing Datsenko, L.I. Auleytner, J. Misiuk, A. Klad'ko, V.P. Machulin, V.F. Bak-Misiuk, J. Zymierska, D. Antonova, I.V. Melnyk, V.M. Popov, V.P. Czosnyka, T. Choinski, J. Structure perfection of the silicon crystals grown by the Czochralski and floating zone methods after implantation with oxygen or neon fast iones followed by annealing at the temperatures T ~ 1050-1150 ⁰0C, when large SiOx precipitates were formed, was studied by means of various X-ray diffraction methods. Considerable increments of integral reflectivities for different Bragg reflections of such samples in comparison with those calculated for a perfect crystal were detected. Broadening of the spatial intensity distribution curves for the Bragg-diffracted beams taken by a single crystal spectrometer as well as the maps of the diffuse isointensity distribution near a reciprocal lattice point, registered by the Philips high-resolution diffractometer, are shown. All of these diffraction effects related to creation of the SiOx precipitates formed on structural damages caused by implantation of oxygen or neon ions and subsequent annealing. Contrary to FZSi, where the appearence of SiOx precipitates was discovered due to intensive diffuse scattering near the layer contained the implanted oxygen ions only, in the case of CZSi samples with larger concentration of oxygen (up to 1*10¹⁸ at/cm³) such defects were formed not only near the burried layer, created by ions of oxygen or neon (with energy E = 4 MeV, dose 10¹⁴cm⁻²) but in a bulk of a crystal. Annealing of the FZSi crystals implanted by oxygen (E ~ 200 keV, dose ~ 10¹⁶-10¹⁷ cm⁻²) at enhanced hydrostatic pressure, additionally stimulated SiOx precipitation close to the implanted layer. 1999 Article Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing / L.I. Datsenko, J. Auleytner, A. Misiuk, V.P. Klad'ko, V.F. Machulin, J. Bak-Misiuk, D. Zymierska, I.V. Antonova, V.M. Melnyk, V.P. Popov, T. Czosnyka, J. Choinski // Semiconductor Physics Quantum Electronics & Optoelectronics. — 1999. — Т. 2, № 1. — С. 56-61. — Бібліогр.: 9 назв. — англ. 1560-8034 PACS: 81.40.- Z,61.66. Bi https://nasplib.isofts.kiev.ua/handle/123456789/117934 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 Structure perfection of the silicon crystals grown by the Czochralski and floating zone methods after implantation with oxygen or neon fast iones followed by annealing at the temperatures T ~ 1050-1150 ⁰0C, when large SiOx precipitates were formed, was studied by means of various X-ray diffraction methods. Considerable increments of integral reflectivities for different Bragg reflections of such samples in comparison with those calculated for a perfect crystal were detected. Broadening of the spatial intensity distribution curves for the Bragg-diffracted beams taken by a single crystal spectrometer as well as the maps of the diffuse isointensity distribution near a reciprocal lattice point, registered by the Philips high-resolution diffractometer, are shown. All of these diffraction effects related to creation of the SiOx precipitates formed on structural damages caused by implantation of oxygen or neon ions and subsequent annealing. Contrary to FZSi, where the appearence of SiOx precipitates was discovered due to intensive diffuse scattering near the layer contained the implanted oxygen ions only, in the case of CZSi samples with larger concentration of oxygen (up to 1*10¹⁸ at/cm³) such defects were formed not only near the burried layer, created by ions of oxygen or neon (with energy E = 4 MeV, dose 10¹⁴cm⁻²) but in a bulk of a crystal. Annealing of the FZSi crystals implanted by oxygen (E ~ 200 keV, dose ~ 10¹⁶-10¹⁷ cm⁻²) at enhanced hydrostatic pressure, additionally stimulated SiOx precipitation close to the implanted layer.
format Article
author Datsenko, L.I.
Auleytner, J.
Misiuk, A.
Klad'ko, V.P.
Machulin, V.F.
Bak-Misiuk, J.
Zymierska, D.
Antonova, I.V.
Melnyk, V.M.
Popov, V.P.
Czosnyka, T.
Choinski, J.
spellingShingle Datsenko, L.I.
Auleytner, J.
Misiuk, A.
Klad'ko, V.P.
Machulin, V.F.
Bak-Misiuk, J.
Zymierska, D.
Antonova, I.V.
Melnyk, V.M.
Popov, V.P.
Czosnyka, T.
Choinski, J.
Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
Semiconductor Physics Quantum Electronics & Optoelectronics
author_facet Datsenko, L.I.
Auleytner, J.
Misiuk, A.
Klad'ko, V.P.
Machulin, V.F.
Bak-Misiuk, J.
Zymierska, D.
Antonova, I.V.
Melnyk, V.M.
Popov, V.P.
Czosnyka, T.
Choinski, J.
author_sort Datsenko, L.I.
title Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
title_short Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
title_full Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
title_fullStr Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
title_full_unstemmed Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
title_sort structure perfection variations of si crystals grown by czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing
publisher Інститут фізики напівпровідників імені В.Є. Лашкарьова НАН України
publishDate 1999
url https://nasplib.isofts.kiev.ua/handle/123456789/117934
citation_txt Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing / L.I. Datsenko, J. Auleytner, A. Misiuk, V.P. Klad'ko, V.F. Machulin, J. Bak-Misiuk, D. Zymierska, I.V. Antonova, V.M. Melnyk, V.P. Popov, T. Czosnyka, J. Choinski // Semiconductor Physics Quantum Electronics & Optoelectronics. — 1999. — Т. 2, № 1. — С. 56-61. — Бібліогр.: 9 назв. — англ.
series Semiconductor Physics Quantum Electronics & Optoelectronics
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last_indexed 2025-11-27T15:38:10Z
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fulltext 5 6 © 1999, Institute of Semiconductor Physics, National Academy of Sciences of Ukraine Semiconductor Physics, Quantum Electronics & Optoelectronics. 1999. V. 2, N 1. P. 56-61. 1. Introduction The SiO x precipitates surrounded by system of disloca- tion loops appearing in silicon crystals containing oxy- gen impurity due to solid solution decay at high temper- atures play an important role as intrinsic gettering cen- tres for cleaning active zones of semiconductor devices from undesirable impurities [1]. Usually, these defects are formed on various initial structure distortions (asso- ciations of various point defects) existing in as-grown crystals after preliminary low temperature treatment [2]. Structure distortions induced in crystals by irradiation with various particles (neutrons, atoms, electrons) of high energy or during technological processes of active impu- rity implantation can also play the role of such centres [3, 4]. Therefore, it is interesting to make clear an effect of implantation of silicon crystals with oxygen because just this impurity play an important role in creation of initial stages of large SiO x precipitates. It is known [5] that the processes of SiO x formation in a silicon con- taining oxygen can considerably change the integral char- acteristics of structure perfection of a crystal, namely: its reflectivity, the Debye-Waller factor, coeficient of ex- tinction. Analysing character of these parameter varia- tions, one can judge of the structural transformation in a crystal and determine the character of existing defects. The aim of this paper was the investigation of structure perfection variations in a crystal by means of different X-ray diffraction methods after annealing the samples implanted by accelerated ions of chemically active oxy- PACS: 81.40.- Z,61.66. Bi Structure perfection variations of Si crystals grown by Czochralski or floating zone methods after implantation of oxygen or neon atoms followed by annealing L. I. Datsenko1, J. Auleytner2, A. Misiuk3, V. P. Klad�ko1, V. F. Machulin1, J. B¹k-Misiuk2, D. ¯ymierska2, I. V. Antonova4, V. M. Melnyk1, V. P. Popov4, T. Czosnyka5 and J. Choiñski5 1 Institute of Semiconductor Physics, National Academy of Sciences of Ukraine, Kyiv, 252028, Ukraine 2 Institute of Physics, al. Lotników 32/46, 02-668 Warsaw, Poland 3 Institute of Electron Technology, al. Lotników 32/46, 02-668 Warsaw, Poland 4 Institute of Semiconductor Physics, RAS, Nauki prosp., 13 , 630090 Novosibirsk, Russia 5 Heavy Ion Laboratory of Warsaw University, V. Pasteura 5a, 02-093 Warsaw, Poland Abstract. Structure perfection of the silicon crystals grown by the Czochralski and floating zone methods after implantation with oxygen or neon fast iones followed by annealing at the tempera- tures T ~ 1050-1150 0C, when large SiO x precipitates were formed, was studied by means of vari- ous X-ray diffraction methods. Considerable increments of integral reflectivities for different Bragg reflections of such samples in comparison with those calculated for a perfect crystal were detected. Broadening of the spatial intensity distribution curves for the Bragg-diffracted beams taken by a single crystal spectrometer as well as the maps of the diffuse isointensity distribution near a recip- rocal lattice point, registered by the Philips high-resolution diffractometer, are shown. All of these diffraction effects related to creation of the SiO x precipitates formed on structural damages caused by implantation of oxygen or neon ions and subsequent annealing. Contrary to FZSi, where the appearence of SiO x precipitates was discovered due to intensive diffuse scattering near the layer contained the implanted oxygen ions only, in the case of CZSi samples with larger concentration of oxygen (up to 1*1018 at/cm3) such defects were formed not only near the burried layer, created by ions of oxygen or neon (with energy E = 4 MeV, dose 1014cm-2) but in a bulk of a crystal. Annealing of the FZSi crystals implanted by oxygen (E ~ 200 keV, dose ~ 1016-1017 cm-2) at enhanced hydro- static pressure, additionally stimulated SiO x precipitation close to the implanted layer. Keywords: Czochralski and floating zone silicon, SiO x precipitates, radiation damages, oxygen and neon ions, Bragg-diffraction of X-ray, reflectivity, Debye-Waller static factor. Paper received 26.02.99; revised manuscript received 04.05.99; accepted for publication 24.05.99. L. I. Datsenko et al.: Structure perfection variations of Si crystals grown by ... 57SQO, 2(1), 1999 gen or neutral atoms (neon) having approximate mass- es. For this purpose, Si crystals grown by Czochralski and floating zone methods, containing different quanti- ty of �grown-in� oxygen atoms, were used. Thus, the process of oxygen solid solution decay was investigated in the samples with radiation defects (with or almost without �grown-in� interstitial oxygen atoms). 2. Materials and methods Three Si samples of the first series I, samples 1, 2, and 3, of (100) surface orientation and of thickness about 3,0 mm, containing rather high concentration C 0 of oxy- gen (up to ~ 10 18 cm -3) were grown by Czochralski meth- od (CzSi). The samples 2 and 3 were irradiated with neon and oxygen ion beams of energy 4 MeV/u and dose 1014 particles/cm2 from the Warsaw Cyclotron [6]. The implantation was performed by uniformly defocused beam at room temperature. The sample 1 was kept as a reference one. The implanted CzSi samples were next an- nealed at 1050 0C for 5h in the atmosphere consisting of argon (80 %) and oxygen (20 %) to create SiO x precipi- tates on the radiation damages. The annealed samples are noted as 1′, 2′ and 3′. Because of a large concentra- tion of oxygen in CzSi, SiO x precipitates were formed not only near the surface subjected to irradiation but in the bulk of these crystals. Six Si samples of the second (II) series, (1 - 6 ), were grown by the floating zone (FZ) method and had low oxygen concentrations (up to C o ~ 1016 cm-3 ). All of them had (111) orientation and were subjected to implantation with oxygen ions of 200 keV energy and doses 1016 ÷ 1017 cm-2. Local maximum concentration C ol in the burried layer situated on the depth close to 0,4 µm (thickness ∆t ~ 0.09 µm) was estimated to reach 4 ×1021 ÷ 4 ×1022 cm-3. Then the samples 1 - 6 of the second series were an- nealed at 1130 °C in the argon atmosphere using high hydrostatic pressure P (up to 12 kbar). It was done to promote the process of SiO x formation [7] in the near- surface layer containing implanted oxygen ions. The tech- nological parameters of annealing of the FZSi crystals are given in the Table 1. Structure perfection changes were investigated by means of a set of X-ray diffractometrical methods based on the Bragg case of diffraction [7]. For characterization of the structure state (appearence of distortions connected with defects) the increments ∆R i of the measured integral reflectivities R i for different Bragg diffraction maxima after various treatments (implantation with oxygen or neon ions or annealing), relatively to the values R i p , calculated for a perfect crystal, were used : ∆R i = R i � R i p = R i p L + 2LR i k . (1 ) Here: R i k is the kinematical reflectivity for an ideal- mosaic crystal. Thus, analysing the ∆R i increments, one could determine the static Debye-Waller factors L after Fig. 1. Spatial intensity distributions (SID) of the Bragg diffracted beams of AgKα radiation in the samples (the first series) after irradiation by high energy ions (E = 4MeV/u, dose 1014 particles/cm2) and annealing (1050 0C, 5 h). Non-implanted sample � 1′, sample implanted with neon � 2′ and oxygen � 3′ ions. 0,00 0,01 0,02 0,03 0,04 0,05 0 1 2 3' 2' 1' t , cm I / I 0 *1 0 5 , a rb .u n its L. I. Datsenko et al.: Structure perfection variations of Si crystals grown by ... 5 8 SQO, 2(1), 1999 various treatments of the samples. More exact expression for the ∆R i can be obtained from the De-Marco and Weiss formulae [8] which were successfully used for experimental data interpretation [5]. Additionally, the spatial intensity distribution (SID) of diffracted beams in a real space by single crystal spectrometer and two-dimensional maps of the diffuse intensity countors near the reciprocal lattice point were obtained by a Philips high-resolution diffractometer. The last method was used, however, for investigation of the FzSi only. Both of these methods permitted us to judge qualitatively the structural state of the samples. 3. Results and discussion Let us start with discussion of the results obtained for samples of the first series. In Fig. 1 the SID as a function of the depth scattering, t, is presented. For the sample 3` Number of the sample Type of treatment Ion dose (cm-2) Annealing parameters (temperature, pressure, duration) 1 implanted only 1016 - 2 implanted and annealed 1016 11300C,1 bar,10 h +11300C,12 kbar,5 h 3 the same 1017 11300C,1 bar,5 h 4 the same 1017 11300C,12 kbar,5 h 5 the same 1016 11300C,6 kbar,5 h 6 the same 1016 11300C,1 bar,10 h Table 1. The technological parameters of annealing the FZSi samples (second series). Number of the crystal 220 440 660 880 ∆R i 107 L 220 ∆R i 107 L 440 ∆R i 107 L 660 ∆R i 107 L 880 1 2,5 - 3,3 - 7,3 0.018 2,7 0.03 2 18,0 0.002 23,0 0.01 11,0 0.028 5,3 0.07 3 8,4 0.001 3,6 0.002 6,5 0.016 1,7 0.02 1′ 121,0 0.01 48,0 0.02 20,0 0.05 4,2 0.05 2′ 68,0 0.006 32,0 0.015 15,0 0.04 2,7 0.035 3′ 156,0 0.013 67,0 0.032 23,7 0.06 4,4 0.056 Table 2. Integral perfection characteristics of the first series samples, i.e., increments of reflectivities ∆∆∆∆∆R i and Debye-Waller static factors L for as grown (1), irradiated (2, 3) and annealed (1′′′′′, 2′′′′′,3′′′′′) crystals measured for 220, 440, 660, 880 Bragg reflections of AgKααααα radiation. Notes: The Czochralski grown Si samples: (1) � as grown, (2) � implanted with neon ions, and (3) � implanted with oxygen ions respectively. Figures 1′, 2′, 3′ designate the same crystals annealed at 1050 °C for 5 h. The depthes of X- ray penetrating in Si under the Bragg diffraction conditions (extinction length Λ) are equal to 50, 71, 120, 205 µm for 220, 440, 660 and 880 reflections of AgKα radiation, respectively. L. I. Datsenko et al.: Structure perfection variations of Si crystals grown by ... 59SQO, 2(1), 1999 irradiated with the oxygen ions the noticeable broaden- ing of the curve in comparison with those of the samples 1′ and 2′ is seen indicating more intensive X-ray diffuse scattering on the SiO x precipitates formed during anneal- ing just near the surface of the sample. One can see also less intensive tails of diffuse scattering for the samples 1′ and 2′. It means that during annealing the SiO x precipi- tates were formed not only on the radiation damages created by the Ne ions, but also in the bulk of non-irra- diated sample 1′. The results of the reflectivity increment measurements after irradiation of the CzSi samples and their successive annealing are given in Table 2. An enhancement of the R i is seen for the irradiated samples (2, 3) due to creation of distorted zones near the surface where the accelerated ions stoped. The most noticeable distortions were creat- ed in the case of the neutral neon atoms which did not interact chemically with the silicon matrix. For both of the samples 2 and 3 the largest ∆R i changes were re- vealed for the Bragg reflections of low orders (220 and 440) for which the depths of diffraction maximum for- mation (extinction length, Λ) are equal 50µm and 71 µm, respectively. It may mean that the damaged zones af- fecting the ∆R i changes were situated somewhere between the surface and these depths. More drastic changes of the ∆R i were discovered in the samples 1′, 2′ and 3′ of the first series after their an- nealing at 1050 °C for 5 hours, probably due to inten- sive SiO x precipitates appearing. The largest R i incre- ment, 156 ·10-7, characterises the sample 3′ irradiated with oxygen. This result is in agreement with the the SID for the the Bragg diffracted beam presented in Fig. 1 where the largest broadening of the curve 3′ is shown. So, one can suppose that the oxygen ions created higher local concentration of this impurity and, therefore, more favourable conditions for oxygen solid solution decay during annealing of the crystal as comparing with the case of neon ions. Let us consider now the results obtained after anneal- ing of the FZSi samples, implanted by oxygen (series II). At first we analyse peculiarities of the SID for the Bragg diffracted beams in the samples 1 - 4, presented in Fig. 2. The broadest curve corresponds to the sample 2 subject- ed not only to implantation with oxygen ions but an- nealings, too (see Table 1). Its large width is connected perhaps with strong diffuse scattering on SiO x precipi- tates appeared during high temperature annealings. The other curves (e.g., 3 and 4), taken from the samples sub- jected to various annealings (of not so long duration as for the sample 2), are narrower. The peak value of the relative intensity I / I 0 , is however, higher in the sample 2 than in as-implanted sample 1 due to contribution of diffuse scattering on SiO x precipitates appearing in def- fects of complex annealing near 1130 °C. The maps of two-dimensional distribution of diffuse scattering intensities near the 333 reciprocal point given in Fig. 3, confirm in general, the above interpretation of SID. Really, the as-implanted sample 1 of series II Fig. 2. Spatial intensity distributions (SID) variations for the samples of second series implanted with oxygen and annealed (symbols are given in Table 1). (1) sample implanted with oxygen only. I 0 is the intensity for incident beams. 0,000 0,002 0,004 0,006 0,008 0,010 0 1 2 3 4 3 2 1 t , cm I / I 0 * 1 0 5 , a rb .u n it s L. I. Datsenko et al.: Structure perfection variations of Si crystals grown by ... 6 0 SQO, 2(1), 1999 Fig. 4. Integral reflectivity increments ∆R i versus the diffrac- tion vector H ~ (h2 + k2 + l2)1/2 for the FZSi crystals after im- plantation with oxygen and annealing. The numbers of sam- ples correspond to those in Table 1. (Fig. 3A) shows the existence of two reciprocal points (one of them relates to the upper thin (~ 0,3 µm) layer near the implanted surface). Subsequent annealing of the FZSi samples 2, 3 resulted in disappearing the discussed second point and in forming the broad pictures of diffuse scattering on SiO x precipitates (Fig. 3C). Now let us discuss the curves of the integral reflectiv- ity increments ∆R i versus a diffraction vector H taken for the 111, 333, 444, 555, and 777 Bragg reflections in the samples 1 - 6 of the second series after various treat- ments (Fig. 4.). Besides these curves, the dotted graph for the extinction length Λ (the depth of diffracted beam penetration) as a functoin of H is also given for relative comparison with the depth of scattering. It can be seen that the main changes in scattering process occured just for the low orders (111 or 333) reflections. It means that the process of oxygen solid solution decay takes place just closely to the implanted layer where the local con- centration C 0l of oxygen could reach level of 1021 or 1022 at/cm3. The sample 1 of the second series is characterised by very high increment of reflectivity, ∆R i , for the 111 re- flection (curve 1 in Fig. 4). The reason of such large chang- es in R i in this sample consists mainly in elastic bending a crystal [9] due to presence of the oxygen burried layer near the implanted surface. Thus, for this sample, the Debye-Waller factor, L, hardly could be calculated from the formula (1). Annealing of the sample 2 (see Table 1) resulted in more considerable increment of ∆R i than that of the sample 1 due to appearence of SiO x precipitates closely to implanted zone and in relaxation of elastic strains. For this sample the volume part of SiO x precipi- tates r 0 , being estimated from the value of ∆R i (r 0 ≈ 2L = 0,036), is the largest among the other crystals because this sample was annealed for 15 h in total at 1130 0C and additionally it was treated under high pres- sure (P = 12 kbar). Concerning an influence of high pressure on the ∆R i increments (Fig. 4), the results for the samples 3 and 4 Fig. 3. Maps of the diffuse scattering taken near 333 reciprocal lattice point for CuKα1 radiation in the samples of the II series subjected to implantation with oxygen ions of energy E ~ ~ 200keV, dose 1016 - 1017 at/cm2 and followed annealing (see table 1). The axes are marked in λ/2d units, where λ is wave- length and d interplanar distance. A � after implantation with O only (dose 1017 cm-2), C � implanted with O, dose 1016 cm-2 and annealed at 11300C, 1 bar, 10 h + 1130 0C, 12 kbar, 5 h. 0 2 4 6 8 10 12 0 1 2 3 6 5 777555444333111 ∆R i= (R i - R ip ) * 1 0 5 , a rb .u n . H =(h 2+k 2+ l 2)1/2 , arb.un. 0 100 200 300 400 500 600 3 4 2 1 Λ σ , µ m L. I. Datsenko et al.: Structure perfection variations of Si crystals grown by ... 61SQO, 2(1), 1999 should be compared. It is easy to see that ∆R i (4) > ∆R i (3) because the first of them was annealed during the same time (5 h) but under higher pressure (P = 12 kbar). So, creation of SiO x precipitates has been more noticeably manifested under an influence of hydrostatic pressure. The same conclusion could be drawn from comparison of the ∆R i for the samples 5 and 6 (∆R i (5) > ∆R i (6)), though the time of treatment was longer for the sample 6. However, comparing the increments of R i for the sam- ples 2 and 4 treated under pressure p = 12 kbar by the same time (5 h) one can conclude that ∆R i (2) > ∆R i (4) because the first of these samples was annealed addition- ally for 10 h, though this preannealing was carried out at ambient pressure (P = 1 bar). 4. Conclusion remarks Structure perfection of the Czochralski grown silicon crystals and of silicon crystals obtained by floating zone method subjected to implantation of oxygen and neon ions and then to annealing at the temperatures, where intensive silicon-oxygen solid solution decay takes place, was studied. Noticeable changes of the increments of in- tegral reflectivities for the Bragg diffracted beams of the hard X-ray radiation and considerable broadening of the spatial intensity distribution curves as well as maps of isointensive diffuse countors near a reciprocal lattice point after the mentioned annealings of both types of crystals in comparison with a perfect crystal were estab- lished. Contrary to FZSi, where intensive diffuse scat- tering caused by appearance of SiO x precipitates near the oxygen-implanted layer was detected only, in the case of CZSi those defects were formed not approximately to the damaged layer but through the bulk. Preferential cre- ation of SiO x precipitates was discovered, however, near the zone of radiation damages caused by high energetic ions of neon and oxygen, especially in the last case. One can suppose that chemically active impurity introduced in silicon matrix creates more favourable conditions for following appearence of SiO x precipitates at high tem- peratures. It was shown that annealing of the implanted FZSi crystals at enhanced hydrostatic pressure in argon at- mosphere additionally stimulated the diffuse scattering intensity due to formation of the mentioned precipitates during process of oxygen solid solution decay close to the implanted layer. Changes of character different dif- fraction phenomena are better displayed after such treat- ments. These changes manifest themselves more distinctly under higher hydrostatic pressure. References 1. A. Borghesi, B. Pivac, A. Sassella, A. Stella, Oxygen precipitates in silicon // J.Appl.Phys.,77, pp.4169-4244 (1995). 2. V. M. Babich, N. I. Bletskan, E. F. Venger, Kislorod v monokri- stallakh kremniya (in Russian) Kiev., Interpress LTD Publishing company (1997).p. 239. 3. X.-T. Meng. Radiation-enhanced oxygen precipitates in neutron- transmutation-doped floating zone silicon // Phys.Stat.Sol.(a)., 129(2), pp.K131-K136 (1992). 4. T. Hallberg, J. L. Lindstrom, Enhanced oxygen precipitates in electron irradiated Si // J.Appl.Phys., 72(11). pp.5130-5138 (1992). 5. L. Datsenko, A. Misiuk, V. Machulin, V. Khrupa, Vliyaniye tem- peratury, hydrostaticheskogo szhatia i drugich fisicheskikh fac- torov na evolyutsiyu structur pri pretsipitatsii kisloroda v krem- nii, Poverchnost // Rentgenovskie, neutronnie i synchrotronniye issledovaniya, 10, pp.122-137 (1998). 6. D. ¯ymierska, D. Klinger, J. Auleytner, T. Czosnyka, L. Datsen- ko. Studies of the near- surface layers of silicon crystals implant- ed with fast ions // Nucl. Instr. and Meth., B 146. pp.350-355 (1998). 7. L. Datsenko, A. Misiuk, J. Härtwig, A. Briginetz, V. I. Khrupa, Influence of preannealing on perfection of CzSi crystals subjected to high pressure treatment // Acta Phys.Polonica, 86(4). pp.585- 590 (1994). 8. J. J. De Marco, R. J. Weiss, The integrated intensities of perfect crystals, 19(1). pp.68-72 (1965). 9. L. I. Datsenko, V. B. Molodkin, M. E. Osinovski, Dynam- icheskoye rasseyanie rentgenovskich luchey realnymi kristallami (in Russian), Naukova dumka publishing company, Kyiv, (1988).

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