Epitaxy of GaAs by the Close‐Spaced Vapor Transport Technique

Côté, D.; Dodelet, Jean‐Pol; Lombos, B. A.; Dickson, J. I.

doi:10.1149/1.2109051

Cited by 29 publications

(4 citation statements)

References 32 publications

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“…For the case of GaAs homoepitaxy, this functional dependence of growth rate on parameters TI, T 2 , d, and x has been verified [50].…”

Section: J -mentioning

confidence: 69%

“…According to the model of Cote et al [50,51], the CSVT growth rate is determined by the flux J of Ga 2 0 molecules incident on the seed surface. This flux originates from the concentration gradient resulting from the relatively high partial pressure of Ga 2 0 at the source wafer and the lower partial pressure of Ga 2 0 at the seed.…”

Section: Advantages Of Csvt/lpz Approachmentioning

confidence: 99%

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Electronic GaAs-on-Silicon Material for Advanced High-Speed Optoelectronic Devices

Mauk¹,

McNeely²

1991

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“…For the case of GaAs homoepitaxy, this functional dependence of growth rate on parameters TI, T 2 , d, and x has been verified [50].…”

Section: J -mentioning

confidence: 69%

Section: Advantages Of Csvt/lpz Approachmentioning

confidence: 99%

Electronic GaAs-on-Silicon Material for Advanced High-Speed Optoelectronic Devices

Mauk¹,

McNeely²

1991

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“…This was the "great" starting period of vapour phase technologies. The second era for CSVT was the second half of the eighties, and the beginning of the nineties [6,7].By that time the vapour phase epitaxy techniques based on halogen transport became widespread and the method based on metal-organic precursors was developed for binary and ternary III-V compounds. Nevertheless CSVT still remained an attractive technology.…”

mentioning

confidence: 99%

“…The possibility to grow semi-insulating (SI) or nearly SI GaAs with controlled EL2 concentration gave a great impact to the use of CSVT [8,9]. Preparation of photovoltaic structures, especially GaAs on Ge heterostructures, was the other dominant direction of CSVT applications [6,10].The second revival, the third era is the present time, when the solar-energy conversion is the main aim. CSVT has been applied to III -Vs, like GaAs on Si, InGaP on GaAs, even combined with LPE method [11,12].…”

mentioning

confidence: 99%

A low temperature photoluminescence study of CSVT grown GaAs epitaxial layers

Somogyi¹,

Varga

Rommeluere

2003

phys. stat. sol. (c)

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PACS 72.80. Ey, 78.55.Cr One of the most important questions in the application of the close spaced vapour transport method of epitaxial growth of various compound semiconductors is the appropriate doping of the growing layer. In this work low temperature photoluminescence spectra were taken on GaAs epitaxial layers grown by water-inhydrogen transport method using n, p, and i (semi-insulating) type conductivity source crystals. Two different water vapour pressures were applied for the experiments. The transport and incorporation of impurities from the source were clearly indicated in combination with some specific, probably defect and/or complex related photoluminescence peaks.Introduction According to some proverbs, cats have three (sometimes nine) lives. Perhaps one can make similar conclusions, when studying the history of semiconductors and technologies of semiconductors. E.g. we have indicated in [1] that this era is the third "life" of GaN. There is a similar situation now for a technological method, for the close space vapour transport (CSVT). The method was proposed (and investigated) in early and mid-sixties [2 -4]. (Though according to words of [5] "such a technique always existed".) This was the "great" starting period of vapour phase technologies. The second era for CSVT was the second half of the eighties, and the beginning of the nineties [6,7].By that time the vapour phase epitaxy techniques based on halogen transport became widespread and the method based on metal-organic precursors was developed for binary and ternary III-V compounds. Nevertheless CSVT still remained an attractive technology. Simplicity, inexpensive setup, absence of toxic gases (and expensive safety systems), high growth rates, etc. characterise this method. The possibility to grow semi-insulating (SI) or nearly SI GaAs with controlled EL2 concentration gave a great impact to the use of CSVT [8,9]. Preparation of photovoltaic structures, especially GaAs on Ge heterostructures, was the other dominant direction of CSVT applications [6,10].The second revival, the third era is the present time, when the solar-energy conversion is the main aim. CSVT has been applied to III -Vs, like GaAs on Si, InGaP on GaAs, even combined with LPE method [11,12]. The basic direction is, in II-VIs. Well known materials have been revived in this technology: ZnO, ZnTe, ZnSe, CdTe, CdIn 2 Te 4 , and there is a new approach to the CIS structures of the greatest importance: CuInSe 2 and CuIn 1-x Ga x Se 2 (only examples: [13,14]). CIS is one of the most fashionable research topics in vogue and, the future of cheap, large area solar cells may depend on the cheap, fast, safe CSVT method.

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Liquid‐Phase Epitaxy

Mauk¹

2023

Digital Encyclopedia of Applied Physics

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Liquid‐phase epitaxy (LPE) is a crystal growth method that produces single‐crystal films or layers of semiconductors and other types of materials on a supporting substrate. LPE‐grown structures include light‐emitting diodes (LEDs), laser diodes, and photodetectors; energy conversion devices such as photovoltaic cells, and various magnetic and optical devices. LPE is typically affected by solidifying a film comprising solute components precipitated from a molten metallic solution at temperatures ranging from several hundred to >1200 °C. A common LPE technology is based on a crucible slider apparatus in a temperature‐programmed furnace with a hydrogen ambient at atmospheric pressure. Multiple layer depositions generate a wide range of structures, and LPE has proven especially useful for III–V compound semiconductor heterostructures. Present‐day uses of LPE stem from favorable features such as fast growth rates, low defect densities, a wide choice of impurity dopants, and straightforward formulations based on phase equilibria and kinetics data and models. While LPE was a prominent epitaxy technology in the 1970s and 1980s, nowadays LPE is relegated to niche applications. Compared to competing epitaxy technologies such as molecular beam epitaxy (MBE) and metal–organic chemical vapor deposition (MOCVD), LPE falls short with regard to the achievement of ultrathin layered structures, strained or lattice‐mismatched structures, abrupt interfaces, and areal uniformity. Still, there are significant application areas well served by LPE or by modified LPE techniques, as reviewed here.

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Epitaxy of GaAs by the Close‐Spaced Vapor Transport Technique

Cited by 29 publications

References 32 publications

Electronic GaAs-on-Silicon Material for Advanced High-Speed Optoelectronic Devices

Electronic GaAs-on-Silicon Material for Advanced High-Speed Optoelectronic Devices

A low temperature photoluminescence study of CSVT grown GaAs epitaxial layers

Liquid‐Phase Epitaxy

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