Direct gap Ge1-ySny alloys: Fabrication and design of mid-IR photodiodes

Senaratne, C. L.; Wallace, P.; Gallagher, John; Sims, Patrick; Kouvetakis, John; Menéndez, José

doi:10.1063/1.4956439

Cited by 39 publications

(24 citation statements)

References 42 publications

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“…1 Attempts to circumvent the quality issues to achieve alloys with y >> 0.15 are based on lowering the growth temperature to about 150 ℃, [2][3][4][5] or using complex buffer layers with intermediate compositions. [6][7][8] However, very few reports have been published on band gaps from such samples, 4,8,9 and the few results available are difficult to compare due to unknown or large strains present, compositional uncertainties, different methodologies for extracting the band gaps, and sample complexity. In this letter, we report on the structural and optical characterization of a series of Ge1-ySny alloys that meet three criteria that reduce the band gap uncertainty and simplify the analysis of optical experiments: first, a smooth and monotonic compositional dependence of the structural properties that is consistent with previous measurements of low-Sn alloys with proven quality; second, small levels of strain that minimize errors associated with deformation potentials and elastic parameters 10 (and their unknown compositional dependence); and third, elimination of buffer layers that make it difficult to extract the optical properties of the Ge1-ySny layer of interest.…”

mentioning

confidence: 99%

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 < y < 0.30): Synthesis, structural, and optical properties

Wallace

Ringwala

et al. 2019

Applied Physics Letters

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Ge1-ySny alloys with compositions in the 0.15 < y < 0.30 range have been grown directly on Si substrates using a chemical vapor deposition approach that allows for growth temperatures as high as 290 o C. The films show structural properties that are consistent with results from earlier materials with much lower Sn concentrations. These include the lattice parameter and the Ge-Ge Raman frequency, which are found to depend linearly on composition. The simplicity of the structures, directly grown on Si, makes it possible to carry out detailed optical studies. Sharp absorption edges are found, reaching 8 μm near y =0.3. The compositional dependence of edge energies shows a cubic deviation from the standard quadratic alloy expression. The cubic term may dramatically impact the ability of the alloys to cover the long-wavelength (8-12 μm) mid-IR atmospheric window. * chixu@asu.edu

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mentioning

confidence: 99%

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 < y < 0.30): Synthesis, structural, and optical properties

Wallace

Ringwala

et al. 2019

Applied Physics Letters

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“…Such detectors, therefore, only operate under cooled conditions, typically between 4 and 78 K. Here, we show that hyperdoped Ge:Au has fundamentally different properties from those of conventional Ge:Au, namely, a much larger sub-band-gap absorption coefficient comparable to that of direct-band-gap semiconductors and room temperature sub-band-gap SWIR photodetection [38]. We note that significant progress has been made on Ge-Sn alloys [39,40], which have recently demonstrated room-temperature SWIR photodetection [41][42][43][44] and lasing [21,45], but which operate by a fundamentally different sub-bandgap absorption mechanism than that of the Au-dopant mediation investigated here. Ge-Sn alloying (∼+9 % Sn) creates high compressive strain, which can induce a redshifted direct-band-gap transition [39,40].…”

Section: Introductionmentioning

confidence: 77%

Gold-Hyperdoped Germanium with Room-Temperature Sub-Band-Gap Optoelectronic Response

et al. 2020

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Short-wavelength-infrared (SWIR; 1.4-3.0 µm) photodetection is important for various applications. Inducing a low-cost silicon-compatible material, such as germanium, to detect SWIR light would be advantageous for SWIR applications compared with using conventional (III-V or II-VI) SWIR materials. Here, we present a scalable nonequilibrium method for hyperdoping germanium with gold for dopantmediated SWIR photodetection. Using ion implantation followed by nanosecond pulsed laser melting, we obtain a single-crystal material with a peak gold concentration of 3 × 10 19 cm −3 (10 3 times the solubility limit). This hyperdoped germanium has fundamentally different optoelectronic properties from those of intrinsic and conventionally doped germanium. This material exhibits sub-band-gap absorption of light up to wavelengths of at least 3 µm, with a sub-band-gap optical absorption coefficient comparable to that of commercial SWIR photodetection materials. We show that germanium hyperdoped with gold exhibits sub-band-gap SWIR photodetection at room temperature, in contrast with previous doped-germanium photodetector studies, which only show a low-temperature response. This material is a potential pathway to low-cost room-temperature silicon-compatible SWIR photodetection.

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“…Mathews et al demonstrated the first photodetectors made from Ge-Sn alloys, and detectors with 2% Sn were shown to cover the entire telecommunications spectrum [49]. Since then, photodetectors with Sn content up to 16% have been achieved using this method [50,51]. The CVD approach using SnD 4 also lead to the first observable luminescence from Ge-Sn alloys.…”

Section: Ge-sn Alloy As An Intrinsically Direct Band Gap Materialsmentioning

confidence: 99%

Towards a direct band gap group IV Ge-based material

Tran

Mathews

Williams

2019

Materials Science in Semiconductor Processing

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A silicon-compatible laser source is of utmost importance for a successful photonic integrated circuit. The conventional solution using direct band gap III-V materials adds significant complexity into the fabrication process because the active materials have to be bonded or grown on a largely mismatched silicon substrate. Recently, germanium has been considered a promising material for silicon photonic applications due to its interesting electronic band structure. Several concepts to realise a direct band gap Ge-based material will be reviewed in this paper, such as: tensile strain combined with high n-type doping, high tensile strain created by micromachining, synthesis of Ge-Sn alloys by chemical vapour deposition and, in particular, synthesis of Ge-Sn alloys by ion implantation followed by pulsed laser melting (PLM). Besides providing a very high level of reproducibility and purity in conventional device fabrication, ion implantation followed by PLM is shown to have potential for realising an intrinsically direct band gap material of high quality. Producing a at Sn 10 . % alloy is now possible and a highly strain-relaxed layer can also be realised by this technique.

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Direct gap Ge1-ySny alloys: Fabrication and design of mid-IR photodiodes

Cited by 39 publications

References 42 publications

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 < y < 0.30): Synthesis, structural, and optical properties

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 < y < 0.30): Synthesis, structural, and optical properties

Gold-Hyperdoped Germanium with Room-Temperature Sub-Band-Gap Optoelectronic Response

Towards a direct band gap group IV Ge-based material

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Direct gap Ge1-ySny alloys: Fabrication and design of mid-IR photodiodes

Cited by 39 publications

References 42 publications

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 &lt; y &lt; 0.30): Synthesis, structural, and optical properties

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 &lt; y &lt; 0.30): Synthesis, structural, and optical properties

Gold-Hyperdoped Germanium with Room-Temperature Sub-Band-Gap Optoelectronic Response

Towards a direct band gap group IV Ge-based material

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Product

Resources

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Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 < y < 0.30): Synthesis, structural, and optical properties

Mid-infrared (3–8 μm) Ge1−ySny alloys (0.15 < y < 0.30): Synthesis, structural, and optical properties