Hydrogen passivation of acceptors in <i>p</i>-InP

Dautremont‐Smith, W. C.; Lopata, J.; Pearton, S. J.; Koszi, L. A.; Stavola, Michael; Swaminathan, V.

doi:10.1063/1.344508

Cited by 85 publications

(15 citation statements)

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“…In agreement with earlier studies using sealed ampoule diffusion [6] and OMVPE diffusion [3], the maximum hole concentration after diffusion but before annealing is between 20-50% of the maximum Zn concentration; this increases to 30-75% after a post-diffusion RTA using the annealing conditions detailed above. Two mechanisms have been proposed to account for the lower hole concentration compared to the total Zn concentration: passivation of the Zn by atomic hydrogen [7,8], or compensation of the substitutional Zn by an interstitial donor [6,9]. An increase in hole concentration after annealing is consistent with either mechanism.…”

Section: Resultsmentioning

confidence: 69%

Multiwafer zinc diffusion in an OMVPE reactor

Pitts

Benyon

Goodchild

et al. 2012

Journal of Crystal Growth

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Section: Resultsmentioning

confidence: 69%

Multiwafer zinc diffusion in an OMVPE reactor

Pitts

Benyon

Goodchild

et al. 2012

Journal of Crystal Growth

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“…In addition the In removal rate depends mostly on the flux of active neutral species, such as CH 3 , and depends only weakly on the flux of ionic species. In contrast the In atom surface density is equal to that of the bulk material N In ϭ5.8ϫ10 14 cm Ϫ2 .…”

Section: Resultsmentioning

confidence: 99%

Proposal for an etching mechanism of InP in CH4-H2 mixtures based on plasma diagnostics and surface analysis

Feurprier

Cardinaud

Grolleau

et al. 1998

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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The influence of CH 4 -H 2 mixture composition and rf power input on the etching mechanism of InP is discussed. Argument is based on etch rate measurements, plasma diagnostics ͑optical emission spectroscopy and mass spectrometry͒ and quasi in situ x-ray photoelectron spectroscopy ͑XPS͒ surface analysis. Results show that the key mechanistic parameters are the CH 3 flux density and the ion energy flux density on the InP surface. The In removal mechanism is the most important feature as it is the one which limits the effective etching and controls the surface stoichiometry. This mechanism depends mostly upon the CH 3 flux but needs ion assistance. On another hand, the P removal mechanism appears to be strictly controlled by the ion energy flux. Based on these observations an analytical model is proposed to describe the etching. The mechanism can be described as an ion-assisted chemical etching mechanism. Its originality is that In and P removal mechanisms are considered separately although they are strongly interdependent as indicated by XPS. A quantitative determination of the CH 3 flux and the ion energy flux density on the InP surface by means of mass spectrometry allow to show that the model is applicable in a wide range of gas mixture composition and rf power. Moreover, it gives an estimation of the number of In atom etched per incident CH 3 in agreement with the generally admitted assumption that trimethylindium is the major etch product of In, and allows an estimation of the surface coverage in methyl radicals.

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“…Hydrogen has been used extensively 4,5,6 to influence the electrical properties of Si and III-V materials as well as a number of heterostructure systems, such as GaAs/Si, 7 GaAs/InP, 8 and epitaxial/homoepitaxial InP/InP. 9 Surprisingly, despite the improvements found for these materials' systems, there has been very little work reported on hydrogen passivation in HgCdTe. This has recently led us, as well as others, 10 to investigate this possibility.…”

Section: Introductionmentioning

confidence: 99%