GaN devices based on nanorods

D. Cherns; L. Meshi; I. Griffiths; S. Khongphetsak; S. V. Novikov; R. P. Campion; C. T. Foxon; C. Liu; P. Shields; W. N. Wang

doi:10.1088/1742-6596/209/1/012001

GaN devices based on nanorods

D. Cherns, L. Meshi, I. Griffiths, S. Khongphetsak, S. V. Novikov, R. P. Campion, C. T. Foxon, C. Liu, P. Shields, W. N. Wang

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Transmission and scanning electron microscopy are used to examine the role of an intermediate nanorod layer in reducing threading defect densities in GaN/(0001)sapphire. Films grown by molecular beam epitaxy under N-rich conditions showed Ga-polar nanorods growing out of a more compact N-polar layer. The nanorods sometimes contained extended threading defects, which were faulted dipoles lying on {10-10} planes with a displacement vector of 1/2[0001], which act as sources for spiral growth. By overgrowing the nanorods under Ga-rich conditions, continuous epilayers were formed with threading defect densities down to 10⁸ cm^-2. In a second approach, nanorods produced by etching through a self-organised layer of Ni islands were overgrown by metal-organic chemical vapour deposition, to produce overlayers with defect densities down to 5*10⁷ cm^-2. In both cases, the mechanisms by which the nanorod layer reduces the threading defect density are identified.

Original language	English
Article number	012001
Journal	Journal of Physics: Conference Series
Volume	209
DOIs	https://doi.org/10.1088/1742-6596/209/1/012001
State	Published - 2010
Externally published	Yes

Funding

Funders	Funder number
Engineering and Physical Sciences Research Council	EP/D080762/1

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10.1088/1742-6596/209/1/012001

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title = "GaN devices based on nanorods",

abstract = "Transmission and scanning electron microscopy are used to examine the role of an intermediate nanorod layer in reducing threading defect densities in GaN/(0001)sapphire. Films grown by molecular beam epitaxy under N-rich conditions showed Ga-polar nanorods growing out of a more compact N-polar layer. The nanorods sometimes contained extended threading defects, which were faulted dipoles lying on {10-10} planes with a displacement vector of 1/2[0001], which act as sources for spiral growth. By overgrowing the nanorods under Ga-rich conditions, continuous epilayers were formed with threading defect densities down to 108 cm-2. In a second approach, nanorods produced by etching through a self-organised layer of Ni islands were overgrown by metal-organic chemical vapour deposition, to produce overlayers with defect densities down to 5*107 cm-2. In both cases, the mechanisms by which the nanorod layer reduces the threading defect density are identified.",

author = "D. Cherns and L. Meshi and I. Griffiths and S. Khongphetsak and Novikov, {S. V.} and Campion, {R. P.} and Foxon, {C. T.} and C. Liu and P. Shields and Wang, {W. N.}",

year = "2010",

doi = "10.1088/1742-6596/209/1/012001",

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AU - Cherns, D.

AU - Meshi, L.

AU - Griffiths, I.

AU - Khongphetsak, S.

AU - Novikov, S. V.

AU - Campion, R. P.

AU - Foxon, C. T.

AU - Liu, C.

AU - Shields, P.

AU - Wang, W. N.

PY - 2010

Y1 - 2010

N2 - Transmission and scanning electron microscopy are used to examine the role of an intermediate nanorod layer in reducing threading defect densities in GaN/(0001)sapphire. Films grown by molecular beam epitaxy under N-rich conditions showed Ga-polar nanorods growing out of a more compact N-polar layer. The nanorods sometimes contained extended threading defects, which were faulted dipoles lying on {10-10} planes with a displacement vector of 1/2[0001], which act as sources for spiral growth. By overgrowing the nanorods under Ga-rich conditions, continuous epilayers were formed with threading defect densities down to 108 cm-2. In a second approach, nanorods produced by etching through a self-organised layer of Ni islands were overgrown by metal-organic chemical vapour deposition, to produce overlayers with defect densities down to 5*107 cm-2. In both cases, the mechanisms by which the nanorod layer reduces the threading defect density are identified.

AB - Transmission and scanning electron microscopy are used to examine the role of an intermediate nanorod layer in reducing threading defect densities in GaN/(0001)sapphire. Films grown by molecular beam epitaxy under N-rich conditions showed Ga-polar nanorods growing out of a more compact N-polar layer. The nanorods sometimes contained extended threading defects, which were faulted dipoles lying on {10-10} planes with a displacement vector of 1/2[0001], which act as sources for spiral growth. By overgrowing the nanorods under Ga-rich conditions, continuous epilayers were formed with threading defect densities down to 108 cm-2. In a second approach, nanorods produced by etching through a self-organised layer of Ni islands were overgrown by metal-organic chemical vapour deposition, to produce overlayers with defect densities down to 5*107 cm-2. In both cases, the mechanisms by which the nanorod layer reduces the threading defect density are identified.

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GaN devices based on nanorods

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