Chemical Vapor Deposition of Epitaxial Silicon from Silane at Low Temperatures: I . Very Low Pressure Deposition

Comfort, J.H.; Reif, R.

doi:10.1149/1.2097378

Cited by 85 publications

(24 citation statements)

References 40 publications

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“…[1][2][3][4][5] In our recent study of CVD Si at 600-750°C and 20-80 Torr in a lamp-heated single-wafer reactor, 5 the apparent activation energy for epi-Si is 2.1 eV and that for poly-Si 1.6 eV, in agreement with earlier published results. 1,3,6 Under these deposition conditions, first-order reaction kinetics was found for the ͑average͒ growth rate of epi-Si as well as for poly-Si with respect to the partial pressures of SiH 4 .…”

supporting

confidence: 85%

Effects of Growth Kinetics and Surface Emissivity on Chemical Vapor Deposition of Silicon in a Lamp-Heated Single-Wafer Reactor

Pejnefors¹,

Zhang²,

Radamsson³

et al. 2001

Electrochem. Solid-State Lett.

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Chemical vapor deposition of Si in a lamp-heated single-wafer reactor is studied by monitoring the growth rate of films deposited on bare Si, silicon-on-insulator ͑SOI͒, and oxidized Si wafers. The growth rate is consistently higher for deposition of polycrystalline Si than for epitaxy of Si, due to different kinetics dictating the two depositions. Epitaxy of Si on SOI shows a higher overall growth rate than on bare Si. Likewise, deposition of polycrystalline Si on oxidized Si wafer with a 4000 Å thick oxide has a higher growth rate than on that with 15 Å oxide. These are attributed to surface emissivity variation during Si deposition. The difference in kinetics plays a more dominant role than the surface emissivity variation in affecting the growth rate for the depositions studied.Chemical vapor deposition ͑CVD͒ of epitaxial Si ͑epi-Si͒ and that of polycrystalline Si ͑poly-Si͒ are characterized with different apparent activation energies in the surface reaction limited regime. 1-5 In our recent study of CVD Si at 600-750°C and 20-80 Torr in a lamp-heated single-wafer reactor, 5 the apparent activation energy for epi-Si is 2.1 eV and that for poly-Si 1.6 eV, in agreement with earlier published results. 1,3,6 Under these deposition conditions, first-order reaction kinetics was found for the ͑average͒ growth rate of epi-Si as well as for poly-Si with respect to the partial pressures of SiH 4 . However, the ͑average͒ growth rate depended more strongly on the partial pressure of H 2 for epi-Si compared to poly-Si. These differences in growth kinetics were attributed to a higher H surface coverage for epi-Si than for poly-Si. Hence the growth rate of epi-Si is limited by H 2 desorption whereas the growth rate of poly-Si is limited by the balance between the SiH 4 adsorption and the H 2 desorption. 5 As a result, an appreciable difference in thickness of the two types of Si layers is observed under identical deposition conditions. 5 Since the susceptor for bedding the Si wafer is heated by lamp radiation, variation of wafer surface emissivity during Si deposition leading to wafer temperature alternation could also result in different growth rates for epi-Si on bare Si substrates and poly-Si on oxidized Si wafers. [7][8][9] The purpose of the present study is to identify the dominant effect on growth rate, i.e., deposition kinetics vs. wafer surface emissivity.The single-wafer reactor used in this study was a commercial ASM Epsilon-2000 system whose cross section is shown schematically in Fig. 1. The whole graphite susceptor of 240 ϫ 280 mm size is coated with SiC to prevent contamination. It is heated by two tungsten-halogen lamp-banks above and below together with four lamps ͑not shown͒ located under the susceptor and centered around the rotating axis. A part of the susceptor is set to rotation to improve thickness uniformity over a wafer. The susceptor temperature is measured with three thermocouples placed in the surrounding fixed part ͑front, rear, and side͒ and one encapsulated in the middle of the rotating part. ...

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supporting

confidence: 85%

Effects of Growth Kinetics and Surface Emissivity on Chemical Vapor Deposition of Silicon in a Lamp-Heated Single-Wafer Reactor

Pejnefors¹,

Zhang²,

Radamsson³

et al. 2001

Electrochem. Solid-State Lett.

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“…͑6͔͒ proceeds faster at high temperature. 40 In the low-pressure region (ϳ1 Torr and below͒ it has been reported that the Si growth rate is independent of the hydrogen partial pressure, 11,29,39,43 this behavior could also be described by Eq. ͑11͒.…”

Section: ͑10͒mentioning

confidence: 96%

“…1-5, the deposition kinetics for Si growth is studied. Several publications were found in the literature about the deposition kinetics of epitaxial 15,28-33 and polycrystalline 28,29,31,32,[34][35][36][37][38][39][40] Si film growth from silane performed at deposition pressure ranging from ultrahigh vacuum ͑UHV͒ to atmospheric pressure. Two reaction paths describing the Si growth are homogeneous and heterogeneous decomposition of silane and Si hydrides.…”

Section: Growth Kineticsmentioning

confidence: 99%

Chemical vapor deposition of undoped and in-situ boron- and arsenic-doped epitaxial and polycrystalline silicon films grown using silane at reduced pressure

Pejnefors

Zhang

Radamson

et al. 2000

Journal of Applied Physics

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“…1 A low growth temperature ͑400-700°C͒ prevents the deleterious effects of autodoping from the substrate and lateral diffusion from contacts. To achieve such a low temperature growth, various techniques, such as ultrahigh vacuum chemical vapor deposition ͑UHV-CVD͒, 1,2 very low pressure CVD, 3 plasma enhanced CVD, 4 and low pressure UHV electron-cyclotron-resonance ͑ECR͒ CVD [5][6][7][8] have been used. The advantages of ECR-CVD are the low particulate production in the reactor, enhanced growth rate at low temperatures, and the ability to control plasma potentials, and hence ion bombardment of the substrate, during growth.…”

mentioning

confidence: 99%

Low temperature epitaxial silicon film growth using high vacuum electron-cyclotron-resonance plasma deposition

DeBoer

Dalal

Chumanov

et al. 1995

Applied Physics Letters

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We report on the growth technique and electrical properties of epitaxial Si films grown at low temperatures using an electron-cyclotron-resonance plasma deposition technique. We have used standard high vacuum apparatus to grow high quality films at 450-525°C. A critical step in achieving high quality films is an in situ hydrogen plasma cleaning of the wafer before growth. We have systematically studied the influence of ion bombardment during growth by biasing the substrate, and find that the films are crystalline for substrate bias voltages less negative than about Ϫ15 V, but become polycrystalline as the magnitude of the negative bias is increased. The crystallinity of the film was measured using Raman spectroscopy. The undoped films are n type with carrier concentrations in the 10 16 -10 17 cm Ϫ3 range. The Hall mobilities measured for the films are comparable to values obtained in bulk Si crystals. We can achieve abrupt profiles in carrier concentrations between the heavy doped substrate and the epilayer, with no evidence of diffusion. © 1995 American Institute of Physics.Low temperature epitaxial growth of silicon is of significant current interest due to its potential for making devices with small feature sizes.1 A low growth temperature ͑400-700°C͒ prevents the deleterious effects of autodoping from the substrate and lateral diffusion from contacts. To achieve such a low temperature growth, various techniques, such as ultrahigh vacuum chemical vapor deposition ͑UHV-CVD͒, 1,2 very low pressure CVD, 3 plasma enhanced CVD, 4 and low pressure UHV electron-cyclotron-resonance ͑ECR͒ CVD [5][6][7][8] have been used. The advantages of ECR-CVD are the low particulate production in the reactor, enhanced growth rate at low temperatures, and the ability to control plasma potentials, and hence ion bombardment of the substrate, during growth. In this paper, we report on a systematic study of conditions leading to the growth of very high quality Si films using a controlled, low pressure ECR plasma of silane and hydrogen at low temperatures ͑450-525°C͒.The growth apparatus is similar to the one used in previous work by Mui et al. 8 and Tae et al. 6 However, unlike these previous authors, we did not use a UHV system, but merely a standard high vacuum system equipped with O-rings. The system has previously been described in detail. 9The base pressure in the system is in the range of 5 -9 ϫ10 Ϫ8 Torr. These vacuum conditions require the growth rate to be maximized in order to reduce the incorporation of impurities as previously described by Comfort and Reif. 3 Most of the current techniques for growing epitaxial silicon films below 600°C require UHV conditions due to their extremely low growth rates ͑Ͻ1 Å/s͒. 2,[5][6][7][8] In contrast, the enhanced surface mobility of radicals due to ion bombardment in the ECR plasma allows typical growth rates of more than 3.5 Å/s to be achieved. The growth rate in this type of system is very sensitive to the process conditions, especially the pressure, and silane to hydrogen ratio. W...

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Chemical Vapor Deposition of Epitaxial Silicon from Silane at Low Temperatures: I . Very Low Pressure Deposition

Cited by 85 publications

References 40 publications

Effects of Growth Kinetics and Surface Emissivity on Chemical Vapor Deposition of Silicon in a Lamp-Heated Single-Wafer Reactor

Effects of Growth Kinetics and Surface Emissivity on Chemical Vapor Deposition of Silicon in a Lamp-Heated Single-Wafer Reactor

Chemical vapor deposition of undoped and in-situ boron- and arsenic-doped epitaxial and polycrystalline silicon films grown using silane at reduced pressure

Low temperature epitaxial silicon film growth using high vacuum electron-cyclotron-resonance plasma deposition

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