Physical structure of molecular-beam epitaxy growth defects in HgCdTe and their impact on two-color detector performance

Buell, A. A.; Pham, L. T.; Newton, Michael; Venzor, G. M.; Norton, E. M.; Smith, E. P. G.; Varesi, J. B.; Harper, V. B.; Johnson, S. M.; Coussa, R. A.; Leon, Theresa De; Roth, J. A.; Jensen, J. Eric

doi:10.1007/s11664-004-0064-3

Cited by 16 publications

(6 citation statements)

References 12 publications

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“…Defects have been identified as voids, tellurium precipitates and CdTe dust. We confirm the negative effects of these defects on device performance as it is regularly shown [13]. The etch-pit density (EPD) measured on HgCdTe/Ge by using the Hännert and Schenk solution [14] is on the few 10 6 /cm² range when using a CdTe/Ge buffer layer which is not lattice matched to HgCdTe.…”

Section: Hetero Epitaxial Layers Characterizationsupporting

confidence: 82%

MWIR focal plane arrays made with HgCdTe grown by MBE on germanium substrates

et al. 2006

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The possibility to grow HgCdTe by Molecular Beam Epitaxy (MBE) on large alternative substrates opens the way of increasing the size and reducing the cost of infrared FPAs operating in the Medium Wave InfraRed (MWIR) bands. Germanium was chosen several years ago at Leti because its 'in situ' and 'ex situ' surface preparations are much easier to control compared to the more conventionally used silicon alternative substrate. Moreover extremely high quality germanium "epiready" substrates are commercially available at a reasonable cost for wafer sizes up to 8 inches. MWIR HgCdTe wafers grown today by Defir (LETI/Sofradir joint laboratory) on germanium (up to 4 inches diameter) using MBE, exhibit electrical and physical properties that enables the fabrication of FPAs with various sizes (320x256, 640x512, 1280x1024) and pitches (from 30µm to 15µm) with electro-optical performances similar to the standard process based on the more conventional epilayers of HgCdTe grown on CdZnTe by Liquid Phase Epitaxy (LPE). Due to the low microscopic and macroscopic defect density that can be obtained on such wafers, operabilities above 99.9% are reached today. A status of this MBE growth technology is presented as well as the FPAs performances, including conventional industrial products manufactured such as 320x256 (pitch 30µm), 640x512 (pitch 15µm) and the largest 1280x1024 (pitch of 15µm) more recently available.

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Section: Hetero Epitaxial Layers Characterizationsupporting

confidence: 82%

MWIR focal plane arrays made with HgCdTe grown by MBE on germanium substrates

et al. 2006

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“…Large void defects with sizes from several micrometers to tens of micrometers are the most common defect in MBE-grown HgCdTe. They arise as a consequence of Hg-deficient growth conditions, and are called either voids, 1,9,[40][41][42][43][44][45][46][47][48][49][50] crater defects, 6,10,22,23 V-shape 37 The directions of the crosshatched lines as well as the characteristic angles are labeled. The arrows show that the crosshatch lines are sometimes terminated by etch pits, namely dislocations in the crystal.…”

Section: Resultsmentioning

confidence: 99%

Surface Morphology and Defect Formation Mechanisms for HgCdTe (211)B Grown by Molecular Beam Epitaxy

Chang

Becker

Grein

et al. 2008

Journal of Elec Materi

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The surface morphology and crystallinity of HgCdTe films grown by molecular beam epitaxy (MBE) on both CdZnTe and CdTe/Si (211)B substrates were characterized using atomic force microscopy (AFM), as well as scanning (SEM) and transmission (TEM) electron microscopy. Crosshatch patterns and sandybeach-like morphologies were commonly found on MBE (211) HgCdTe epilayers grown on both CdZnTe and CdTe/Si substrates. The patterns were oriented along the 213 Â Ã , 231 Â Ã , and 011 Â Ã directions, which were associated with the intersection between the (211) growth plane and each of the eight equivalent HgCdTe slip planes. This was caused by strain-driven operation of slip in these systems with relative large Schmid factor, and was accompanied by dislocation formation as well as surface strain relief. Surface crater defects were associated with relatively high growth temperature and/or low Hg flux, whereas microtwins were associated with relatively low growth temperature and/or high Hg flux. AFM and electron microscopy were used to reveal the formation mechanisms of these defects. HgCdTe/HgCdTe superlattices with layer composition differences of less than 2% were grown by MBE on CdZnTe substrates in order to clarify the formation mechanisms of void defects. The micrographs directly revealed the spiral nature of growth, hence demonstrating that the formation of void defects could be associated with the Burton, Cabrera, and Frank (BCF) growth mode. Void defects, including microvoids and craters, were caused by screw defect clusters, which could be triggered by Te precipitates, impurities, dust, other contamination or flakes. Needle defects originated from screw defect clusters linearly aligned along the 011 Â Ã directions with opposite Burgers vector directions. They were visible in HgCdTe epilayers grown on interfacial superlattices. Hillocks were generated owing to twin growth of void or needle defects on (111) planes due to low growth temperature and the corresponding insufficient Hg movement on the growth surface. Therefore, in addition to nucleation and growth of HgCdTe in the normal two-dimensional layer growth mode, the BCF growth mode played an important role and should be taken into account during investigation of HgCdTe MBE growth mechanisms.

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“…Effects of these defects on device performance have already been reported. 5,6 The mechanism of formation and cause of defects are very complex and diverse. Different authors and groups agree that voids and microvoids are directly related to Hg fluxes and substrate growth temperature.…”

Section: Hgcdte/si Defect Densitymentioning

confidence: 99%

Flexibility of p–n Junction Formation from SWIR to LWIR Using MBE-Grown Hg(1–x)Cd x Te on Si Substrates

Vilela

Harris

Kvaas

et al. 2009

Journal of Elec Materi

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In this paper, we show the versatility of using molecular-beam epitaxy (MBE) for the growth of the mercury cadmium telluride (HgCdTe) system. Abrupt composition profiles, changes in doping levels or switching doping types are easily performed. It is shown that high-quality material is achieved with Hg (1-x) Cd x Te grown by MBE from a cadmium mole fraction of x = 0.15 to x = 0.72. Doping elements incorporation as low as 10 15 cm À3 for both n-type and p-type material as well as high incorporation levels >10 18 cm À3 for both carrier types were achieved. X-ray curves, secondary-ion mass spectrometry (SIMS) data, Hall data, the influence of doping incorporation with cadmium content and growth rate, etch pit density (EPD), composition uniformity determined from Fourier-transform infrared (FTIR) transmission spectroscopy, and surface defect maps from low to high x values are presented to illustrate the versatility and quality of HgCdTe material grown by MBE. All data presented in this work are from layers grown on silicon (112) substrate.

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Physical structure of molecular-beam epitaxy growth defects in HgCdTe and their impact on two-color detector performance

Cited by 16 publications

References 12 publications

MWIR focal plane arrays made with HgCdTe grown by MBE on germanium substrates

MWIR focal plane arrays made with HgCdTe grown by MBE on germanium substrates

Surface Morphology and Defect Formation Mechanisms for HgCdTe (211)B Grown by Molecular Beam Epitaxy

Flexibility of p–n Junction Formation from SWIR to LWIR Using MBE-Grown Hg(1–x)Cd x Te on Si Substrates

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