Probing crystallographic orientation-specific carrier lifetimes in epitaxial Ge/AlAs and InGaAs/InP heterostructures

Hudait, Mantu K.; Johnston, Steve

doi:10.1039/d2ma00260d

Cited by 7 publications

(10 citation statements)

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“…Figure b shows 1/τ eff plotted against 2/ d , which yielded values of ∼114 ± 2 ns and ∼21.3 ± 0.04 cm/s for τ bulk and S , respectively. We recently reported an effective lifetime of >100 ns on unstrained epitaxial Ge grown on a III–V buffer template in our previous work as well . The condition of S ≪ 2D/ d is readily satisfied in this case, considering D ≈ 9 cm 2 /s, extracted from Hall measurements (not shown here), which enables the determination of τ bulk from eq .…”

Section: Resultsmentioning

confidence: 99%

“…We recently reported an effective lifetime of >100 ns on unstrained epitaxial Ge grown on a III−V buffer template in our previous work as well. 48 The condition of S ≪ 2D/d is readily satisfied in this case, considering D ≈ 9 cm 2 /s, extracted from Hall measurements (not shown here), which enables the determination of τ bulk from eq 3. Discussion regarding the accuracy of S following from ref 49 for the condition of Sd/D < 0.25, which is satisfied in this case, indicates that the extracted S value is accurate to within 4% over the entire range of S values.…”

Section: Materials Quality Characterization Via μ-Pcdmentioning

confidence: 99%

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Interplay Between Strain and Thickness on the Effective Carrier Lifetime of Buffer-Mediated Epitaxial Germanium Probed by the Photoconductance Decay Technique

Bhattacharya

Johnston

Datta

et al. 2023

ACS Appl. Electron. Mater.

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We report contactless effective minority carrier lifetime of epitaxially grown unstrained and in-plane <110> biaxially tensile-strained (001) germanium (ε-Ge) epilayers measured using microwave-reflectance photoconductance decay measurements. Strained Ge epilayers were grown using In x Ga 1−x As linearly graded buffers on (001) GaAs substrates. Using homogeneous excitation of unstrained Ge epilayers, thickness-dependent separation of minority carrier lifetime components under low injection conditions yielded a bulk lifetime of 114 ± 2 ns and low surface recombination velocity of 21.3 ± 0.04 cm/s. More notably, an effective minority carrier lifetime of >100 ns obtained from sub-50 nm 1.6% tensilestrained Ge epilayers showed no degradation relative to the unstrained counterpart. Detailed material characterization using X-ray diffractometry revealed successful strain transfer of 0.61 and 0.89% to the Ge epilayers via In x Ga 1−x As metamorphic buffers and confirms pseudomorphic growth. Lattice coherence observed at the ε-Ge epilayer and In x Ga 1−x As buffer heterointerfaces via transmission electron microscopy substantiates the prime material quality achieved. The relatively high carrier lifetimes achieved are an indicator of excellent material quality and provide a path forward to realize lowthreshold Ge laser sources.

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Section: Resultsmentioning

confidence: 99%

Section: Materials Quality Characterization Via μ-Pcdmentioning

confidence: 99%

Interplay Between Strain and Thickness on the Effective Carrier Lifetime of Buffer-Mediated Epitaxial Germanium Probed by the Photoconductance Decay Technique

Bhattacharya

Johnston

Datta

et al. 2023

ACS Appl. Electron. Mater.

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“…It was believed to be the defect states within the bulk responsible for the low carrier lifetime for the (111)Ge plane. In addition, it was also not clear whether the surface states or metallic nature of this crystal plane is responsible for the low carrier lifetime from this study . However, the different surface trap states were reported within the Si and Ge − semiconductors, and the density of the surface states ( N SS ) in Ge related to its crystallographic orientations varies as N SS ⟨111⟩ < N SS ⟨110⟩ < N SS ⟨100⟩. , However, the (111)Ge surface exhibited high electrical conductivity leading to short carrier lifetime compared to other orientations. − If the (111)Ge surface is passivated with ALD Al 2 O 3 , where trimethylaluminum (TMA, Al(CH 3 ) 3 ) was used as the metal precursor, then the carrier lifetime should improve from the passivated Al 2 O 3 /(111)Ge heterostructure along with other orientations.…”

Section: Introductionmentioning

confidence: 81%

“…In addition, it was also not clear whether the surface states or metallic nature of this crystal plane is responsible for the low carrier lifetime from this study. 50 However, the different surface trap states were reported within the Si 52 and Ge 53−55 semiconductors, and the density of the surface states (N SS ) in Ge related to its crystallographic orientations varies as N SS ⟨111⟩ < N SS ⟨110⟩ < N SS ⟨100⟩. 53,55 However, the (111)Ge surface exhibited high electrical conductivity leading to short carrier lifetime compared to other orientations.…”

Section: Introductionmentioning

confidence: 99%

“…The man-made (100) and (110) or naturally occurring crystal surfaces can exhibit different electronic and photonic properties − with different carrier lifetimes on those surfaces. The carrier recombination properties from the crystallographically oriented (100)Ge, (110)Ge, and (111)Ge were demonstrated, ,, where the (111)Ge surface exhibited a low carrier lifetime compared to other orientations. It was believed to be the defect states within the bulk responsible for the low carrier lifetime for the (111)Ge plane.…”

Section: Introductionmentioning

confidence: 99%

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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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Band Engineering of ErAs:InGaAlBiAs Nanocomposite Materials for Terahertz Photoconductive Switches Pumped at 1550 nm

Acuna,

Wu,

Bork

et al. 2024

Adv Funct Materials

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Terahertz technology has the potential to have a large impact in myriad fields, such as biomedical science, spectroscopy, and communications. Making these applications practical requires efficient, reliable, and low‐cost devices. Photoconductive switches (PCS), devices capable of emitting and detecting terahertz pulses, are a technology that needs more efficiency when working at telecom wavelength excitation (1550 nm) to exploit the advantages this wavelength offers. ErAs:InGaAs is a semiconductor nanocomposite working at this energy; however, high dark resistivity is challenging due to a high electron concentration as the Fermi level lies in the conduction band. To increase dark resistivity, ErAs:InGaAlBiAs material is used as the active material in a PCS detecting Terahertz pulses. ErAs nanoparticles reduce the carrier lifetime to subpicosecond values required for short temporal resolution, while ErAs pins the effective Fermi level in the host material bandgap. Unlike InGaAs, InGaAlBiAs offers enough freedom for band engineering to have a material compatible with a 1550 nm pump and a Fermi level deep in the bandgap, meaning low carrier concentration and high dark resistivity. Band engineering is possible by incorporating aluminum to lift the conduction band edge to the Fermi level and bismuth to keep a bandgap compatible with 1550 nm excitation.

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Probing crystallographic orientation-specific carrier lifetimes in epitaxial Ge/AlAs and InGaAs/InP heterostructures

Abstract: Current silicon (Si) fin transistor relies on (100) and (110) crystallographic oriented surfaces, and the proposed alternate channel transistor technology comprises of material with higher mobility than Si. Crystallographically oriented...

Cited by 7 publications

References 60 publications

Interplay Between Strain and Thickness on the Effective Carrier Lifetime of Buffer-Mediated Epitaxial Germanium Probed by the Photoconductance Decay Technique

Interplay Between Strain and Thickness on the Effective Carrier Lifetime of Buffer-Mediated Epitaxial Germanium Probed by the Photoconductance Decay Technique

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

Band Engineering of ErAs:InGaAlBiAs Nanocomposite Materials for Terahertz Photoconductive Switches Pumped at 1550 nm

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Probing crystallographic orientation-specific carrier lifetimes in epitaxial Ge/AlAs and InGaAs/InP heterostructures

Abstract: Current silicon (Si) fin transistor relies on (100) and (110) crystallographic oriented surfaces, and the proposed alternate channel transistor technology comprises of material with higher mobility than Si. Crystallographically oriented...

Cited by 7 publications

References 60 publications

Interplay Between Strain and Thickness on the Effective Carrier Lifetime of Buffer-Mediated Epitaxial Germanium Probed by the Photoconductance Decay Technique

Interplay Between Strain and Thickness on the Effective Carrier Lifetime of Buffer-Mediated Epitaxial Germanium Probed by the Photoconductance Decay Technique

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

Band Engineering of ErAs:InGaAlBiAs Nanocomposite Materials for Terahertz Photoconductive Switches Pumped at 1550 nm

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