High carrier lifetimes in epitaxial germanium–tin/Al(In)As heterostructures with variable tin compositions

Hudait, Mantu K.; Johnston, Steven W.; Clavel, Michael; Bhattacharya, Shuvodip; Karthikeyan, Sengunthar; Joshi, Rutwik

doi:10.1039/d2tc00830k

Cited by 10 publications

(17 citation statements)

References 64 publications

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“…The material synthesis, compositional and structural analysis of these heterostructure materials systems are discussed elsewhere. 31 Wherein it was shown using high-resolution X-ray diffraction that the GeSn epitaxial layers were of coherent crystalline quality, and the lattice matched sample D had a narrower reciprocal lattice point contour than the compressively strained samples B (B0.53% strain) and C (B0.81% strain), conforming to the need of growing a lattice matched GeSn epitaxial layer. Also characterized were the effective carrier lifetimes of the GeSn epitaxial layers using microwave reflection photoconductive decay technique (m-PCD) probed at 300 K to extract carrier lifetimes of 220 ns, 468 ns and 324 ns for samples B, C and D, respectively.…”

Section: Methodsmentioning

confidence: 99%

“…Also characterized were the effective carrier lifetimes of the GeSn epitaxial layers using microwave reflection photoconductive decay technique (m-PCD) probed at 300 K to extract carrier lifetimes of 220 ns, 468 ns and 324 ns for samples B, C and D, respectively. 31 These material characterization techniques showed the superior quality of the epitaxial GeSn layers.…”

Section: Methodsmentioning

confidence: 99%

“…[1][2][3][4][5][6][7][8][9][10][11][12] Composition of Sn for this transition is stated over a range, since the bowing parameter of Ge 1Ày Sn y in the computation of energy bandgap varies between experimental and first-principles calculations. 21 Additionally, Ge 1Ày Sn y material has inherent advantages, such as: (i) increased direct band transitions of the carriers between conduction and valence bands, improving optical absorption to provide high photodetector responsivities; [22][23][24] (ii) lower effective mass (m eff ) of carriers in the G-valley than L-valley enhances mobility -thereby boosting the ON-current in a low power transistor; 25,26 (iii) compatibility with Si CMOS technology; [27][28][29][30] (iv) high carrier lifetime due to reduced surface roughness 31 by mitigating surface states induced recombination. Hence, a virtually defect-free lattice matched GeSn/InAlAs (or InGaAs) heterostructure is necessary to make better use of Ge 1Ày Sn y material in photonic integrated circuits (PICs) and optoelectronic applications.…”

Section: Introductionmentioning

confidence: 99%

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Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Karthikeyan¹,

Joshi²,

Zhao³

et al. 2023

J. Mater. Chem. C

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Karthikeyan¹,

Joshi²,

Zhao³

et al. 2023

J. Mater. Chem. C

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“…For instance, timeresolved photoluminescence (PL) can hardly be applied to investigate materials at emission wavelengths in the mid-infrared range as high-speed detectors covering this range are not broadly available. Thus, the very few reported time-resolved studies concern Ge 1−x Sn x emitting below 2.3 µm corresponding to a relatively low Sn content * oussama.moutanabbir@polymtl.ca and/or highly compressively strained materials [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

“…Additionally, by investigating spin-dependent optical transitions leveraging the Hanle effect under steady-state excitation, systematic studies combining modeling and magneto-PL analysis of pseudomorphic layers at a Sn content below 10% reported a radiative lifetime in the 0.5-2.5 ns range at 10 K [20]. However, significantly higher carrier lifetimes reaching 450 ns were recently reported for Ge 1−x Sn x (x < 0.06) grown on InAlAs buffer layers as measured by contactless microwave photoconductive decay [21]. This scarcity of studies on carrier dynamics in narrow bandgap Ge 1−x Sn x semiconductors limits the understanding of their fundamental behavior and burdens the development of accurate and predictive models for Ge 1−x Sn x -based mid-infrared optoelectronic devices.…”

Section: Introductionmentioning

confidence: 99%

Radiative Carrier Lifetime in Ge$_{1-x}$Sn$_x$ Mid-Infrared Emitters

Daligou¹,

Attiaoui²,

Assali³

et al. 2023

Preprint

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Ge1−xSnx semiconductors hold the premise for large-scale, monolithic mid-infrared photonics and optoelectronics. However, despite the successful demonstration of several Ge1−xSnx-based photodetectors and emitters, key fundamental properties of this material system are yet to be fully explored and understood. In particular, little is known about the role of the material properties in controlling the recombination mechanisms and their consequences on the carrier lifetime. Evaluating the latter is in fact fraught with large uncertainties that are exacerbated by the difficulty to investigate narrow bandgap semiconductors. To alleviate these limitations, herein we demonstrate that the radiative carrier lifetime can be obtained from straightforward excitation power-and temperaturedependent photoluminescence measurements. To this end, a theoretical framework is introduced to simulate the measured spectra by combining the band structure calculations from the k.p theory and the envelope function approximation (EFA) to estimate the absorption and spontaneous emission. The model computes explicitly the momentum matrix element to estimate the strength of the optical transitions in single bulk materials, unlike the joint density of states (JDOS) model which assumes a constant matrix element. Based on this model, the temperature-dependent emission from Ge0.83Sn0.17 samples at a biaxial compressive strain of −1.3% was investigated. The simulated spectra reproduce accurately the measured data thereby enabling the evaluation of the steady-state radiative carrier lifetimes, which are found in the 3-22 ns range for temperatures between 10 and 300 K at an excitation power of 0.9 kW/cm 2 . For a lower power of 0.07 kW/cm 2 , the obtained lifetime has a value of 1.9 ns at 4 K. The demonstrated approach yielding the radiative lifetime from simple emission spectra will provide valuable inputs to improve the design and modeling of Ge1−xSnx-based devices.

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Carrier Recombination Dynamics of Surface-Passivated Epitaxial (100)Ge, (110)Ge, and (111)Ge Layers by Atomic Layer Deposited Al₂O₃

Hudait

Johnston

Das

et al. 2023

ACS Appl. Electron. Mater.

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Germanium (Ge) and its heterostructures with compound semiconductors offer a unique optoelectronic functionality due to its pseudo-bandgap nature, that can be transformed to a direct bandgap material by providing strain and/or mixing with tin. Moreover, two crystal surfaces, (100)Ge and (110)Ge, that are technologically important for ultralow power fin or nanosheet transistors, could offer unprecedented properties with reduced surface defects after passivating these surfaces by atomic layer deposited (ALD) dielectrics. In this work, the crystallographically oriented epitaxial Ge/AlAs heterostructures were grown and passivated with ALD Al2O3 dielectrics, and the microwave photoconductive decay (μ-PCD) technique was employed to evaluate carrier lifetimes at room temperature. The X-ray photoelectron spectroscopy analysis reveals no role of orientation effect in the quality of the ALD Al2O3 dielectric on oriented Ge layers. The carrier lifetimes measured using the μ-PCD technique were benchmarked against unpassivated Ge/AlAs heterostructures. Excitation wavelengths of 1500 and 1800 nm with an estimated injection level of ∼1013 cm–3 were selected to measure the orientation-specific carrier lifetimes. The carrier lifetime was increased from 390 ns to 565 ns for (100)Ge and from 260 ns to 440 ns for (110)Ge orientations with passivation, whereas the carrier lifetime is almost unchanged for (111)Ge after passivation. This behavior indicates a strong dependence of the measured lifetime on surface orientation and surface passivation. The observed increase (>1.5×) in lifetime with Al2O3-passivated (100)Ge and (110)Ge surfaces is due to the lower surface recombination velocity compared to unpassivated Ge/AlAs heterostructures. The enhancement of carrier lifetime from passivated Ge/AlAs heterostructures with (100)Ge and (110)Ge surface orientations offers a path for the development of nanoscale transistors due to the reduced interface state density.

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High carrier lifetimes in epitaxial germanium–tin/Al(In)As heterostructures with variable tin compositions

Abstract: Group IV-based germanium-tin (Ge1-ySny) compositional materials have recently shown great promise for infrared detection, light emission and ultra-low power transistors. High carrier lifetimes are desirable for enhancing the detection limit...

Cited by 10 publications

References 64 publications

Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Radiative Carrier Lifetime in Ge$_{1-x}$Sn$_x$ Mid-Infrared Emitters

Carrier Recombination Dynamics of Surface-Passivated Epitaxial (100)Ge, (110)Ge, and (111)Ge Layers by Atomic Layer Deposited Al₂O₃

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High carrier lifetimes in epitaxial germanium–tin/Al(In)As heterostructures with variable tin compositions

Abstract: Group IV-based germanium-tin (Ge1-ySny) compositional materials have recently shown great promise for infrared detection, light emission and ultra-low power transistors. High carrier lifetimes are desirable for enhancing the detection limit...

Cited by 10 publications

References 64 publications

Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Lattice matched GeSn/InAlAs heterostructure: role of Sn in energy band alignment, atomic layer diffusion and photoluminescence

Radiative Carrier Lifetime in Ge$_{1-x}$Sn$_x$ Mid-Infrared Emitters

Carrier Recombination Dynamics of Surface-Passivated Epitaxial (100)Ge, (110)Ge, and (111)Ge Layers by Atomic Layer Deposited Al2O3

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Product

Resources

About

Carrier Recombination Dynamics of Surface-Passivated Epitaxial (100)Ge, (110)Ge, and (111)Ge Layers by Atomic Layer Deposited Al₂O₃