X-ray reciprocal-space mapping of strain relaxation and tilting in linearly graded InAlAs buffers

Olsen, J. A.; Hu, Evelyn L.; Lee, S. R.; Fritz, I. J.; Howard, A. J.; Hammons, B. E.; Tsao, Jeffrey Y.

doi:10.1063/1.361410

Cited by 71 publications

(52 citation statements)

References 40 publications

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“…The strain relaxation value obtained from our measurement of the uppermost In 0.7 Al 0.3 As layer is consistent with the results obtained by other researchers on the uppermost layer of linear graded In x Al 1-x As buffer. 30,38 There are two types of dislocations exist in III-V compound semiconductors during strain relaxation process. Those related to group-III atoms at their core and belonging to the shuffle set are known as a dislocation, while those shuffle set dislocations with group-V atoms at their core are known as b type.…”

Section: Strain Relaxation Propertiesmentioning

confidence: 99%

“…It is well established that the formation kinetics of these two types of dislocations are different, which leads to observed asymmetric strain relaxation along both h110i directions. 39 However, from our study on these TFET structures, the strain relaxation value extracted along [1 10] 38 buffer materials. The symmetric relaxation in these layers indicates that the total length of misfit dislocation in each h110i direction is approximately the same.…”

Section: Strain Relaxation Propertiesmentioning

confidence: 99%

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Role of InAs and GaAs terminated heterointerfaces at source/channel on the mixed As-Sb staggered gap tunnel field effect transistor structures grown by molecular beam epitaxy

Zhu

Jain

Vijayaraghavan

et al. 2012

Journal of Applied Physics

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Articles you may be interested inThe structural, morphological, defect properties, and OFF state leakage current mechanism of mixed As-Sb type-II staggered gap GaAs-like and InAs-like interface heterostructure tunnel field effect transistors (TFETs) grown on InP substrates using linearly graded In x Al 1-x As buffer by molecular beam epitaxy are investigated and compared. Symmetric relaxation of >90% and >75% in the two orthogonal h110i directions with minimal lattice tilt was observed for the terminal GaAs 0.35 Sb 0.65 and In 0.7 Ga 0.3 As active layers of GaAs-like and InAs-like interface TFET structures, respectively, indicating that nearly equal numbers of a and b dislocations were formed during the relaxation process. Atomic force microscopy reveals extremely ordered crosshatch morphology and low root mean square roughness of $3.17 nm for the InAs-like interface TFET structure compared to the GaAs-like interface TFET structure of $4.46 nm at the same degree of lattice mismatch with respect to the InP substrates. The GaAs-like interface exhibited higher dislocation density, as observed by cross-sectional transmission electron microscopy, resulting in the elongation of reciprocal lattice point of In 0.7 Ga 0.3 As channel and drain layers in the reciprocal space maps, while the InAs-like interface creates a defect-free interface for the pseudomorphic growth of the In 0.7 Ga 0.3 As channel and drain layers with minimal elongation along the Dx direction. The impact of the structural differences between the two interface types on metamorphic TFET devices was demonstrated by comparing p þ -i-n þ leakage current of identical TFET devices that were fabricated using GaAs-like and InAs-like interface TFET structures. Higher OFF state leakage current dominated by band-to-band tunneling process due to higher degree of defects and dislocations was observed in GaAs-like interface compared to InAs-like interface where type-II staggered band alignment was well maintained. Significantly lower OFF state leakage current dominated by the field enhanced Shockley-Read-Hall generation-recombination process at different temperatures was observed in InAs-like TFET structure. The fixed positive charge at the source/channel heterointerface influences the band lineup substantially with charge density greater than 1 Â 10 12 /cm 2 and the band alignment is converted from staggered gap to broken gap at $6 Â 10 12 /cm 2 . Clearly, InAs-like interface TFET structure exhibited 4Â lower OFF state leakage current, which is attributed primarily to the impact of the layer roughness, defect properties on the carrier recombination rate, suggesting great promise for metamorphic TFET devices for high-performance, and ultra-low power applications. V C 2012 American Institute of Physics.

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Section: Strain Relaxation Propertiesmentioning

confidence: 99%

Section: Strain Relaxation Propertiesmentioning

confidence: 99%

Role of InAs and GaAs terminated heterointerfaces at source/channel on the mixed As-Sb staggered gap tunnel field effect transistor structures grown by molecular beam epitaxy

Zhu

Jain

Vijayaraghavan

et al. 2012

Journal of Applied Physics

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show abstract

“…Reciprocal lattice point (RELP) coordinates are derived from the Ewald sphere construction and diffractometer angular positions ω and 2Θ [4,5] respectively. The RSMs from LM samples were constructed from approximately three-hundred triple-axis ω-2Θ scans (5 asec steps) for ω-offsets spaced 3 asec apart around the (400) and (533) InP substrate RELPs.…”

Section: Reciprocal Space Mapping (Rsm)mentioning

confidence: 99%

“…1b provide reciprocal lattice vector components related directly to both the in-plane and out-ofplane lattice parameters. The large Bragg angles and high (hkl) Miller indices of the (533) planes enable greater sensitivity to strain than the more commonly investigated (400, 224, and/or 115) crystal planes [4][5][6][7]. Because of the higher Miller indices, the measured RSM shown in Fig.…”

Section: Reciprocal Space Mapping (Rsm)mentioning

confidence: 99%

“…High-resolution x-ray diffraction (HRXRD) reciprocal space mapping (RSM) directly measures the in-plane and out-of-plane lattice parameters, strain, and the diffuse x-ray scattering from multilayered semiconductor heterostructures [3][4]. The technique was recently used to characterize strain-relaxation in linear and step-graded InP 1-x As x and In 1-z Al z As buffers grown by molecular beam epitaxy (MBE) [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

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Triple-axis X-ray Reciprocal Space Mapping of In(y)Ga(1-y)As Thermophotovoltaic Diodes Grown on (100) InP Substrates

Dashiell¹,

Ehsani²,

Sander³

et al. 2006

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Tilt investigation of In(Al,Ga)As metamorphic buffer layers on GaAs (001) substrate: A novel technique for tilt determination

Kumar

Biswas

2016

Crystal Research and Technology

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Crystallographic tilt and Surface topography of InGaAs and InAlAs based metamorphic buffer structures on GaAs (001) substrate grown by molecular beam epitaxy (MBE) under varying growth conditions have been investigated. Compressively strained metamorphic buffer layers show anisotropic strain relaxation. A novel tilt determination technique based on X-ray diffraction has been developed which can separate the effect of anisotropic strain. Tilt has been found to depend on compositional grading scheme, growth temperature and surface irregularities. Samples having random surfaces show smaller tilt than that of samples showing regular cross-hatch. At higher growth temperature, reduction of tilt has been observed and correlated with thermal activation of otherwise inactive slip systems at low temperature. At low temperature and also for continuously graded samples, reduction of tilt has been observed and correlated with the slower relaxation that provide the opportunity for all the slip systems to participate and compete.

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X-ray reciprocal-space mapping of strain relaxation and tilting in linearly graded InAlAs buffers

Cited by 71 publications

References 40 publications

Role of InAs and GaAs terminated heterointerfaces at source/channel on the mixed As-Sb staggered gap tunnel field effect transistor structures grown by molecular beam epitaxy

Role of InAs and GaAs terminated heterointerfaces at source/channel on the mixed As-Sb staggered gap tunnel field effect transistor structures grown by molecular beam epitaxy

Triple-axis X-ray Reciprocal Space Mapping of In(y)Ga(1-y)As Thermophotovoltaic Diodes Grown on (100) InP Substrates

Tilt investigation of In(Al,Ga)As metamorphic buffer layers on GaAs (001) substrate: A novel technique for tilt determination

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