SiGe quantum well infrared photodetectors on strained-silicon-on-insulator

Aberl, Johannes; Brehm, Moritz; Fromherz, T.; Schuster, Jeffrey; Frigerio, Jacopo; Rauter, Patrick

doi:10.1364/oe.27.032009

Cited by 19 publications

(19 citation statements)

References 37 publications

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“…Yield: 6.802 g (13.72 mmol, 82%). 1 (60 mL) was prepared in a Schlenk tube. After addition of neat Si 2 Cl 6 (20.86 g, 77.60 mmol) at room temperature, the reaction solution was stirred for 1 h. All volatiles were removed under reduced pressure, and the highly viscous, colorless residue was extracted with n-hexane (40 mL).…”

Section: Synthesis Of CL 3 Si−ph 2 Ge−ph 2 Ge−sicl 3 (1-cl)mentioning

confidence: 99%

Mixed-Substituted Single-Source Precursors for Si_1–xGe_x Thin Film Deposition

et al. 2022

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A series of new mixed-substituted heteronuclear precursors with preformed Si–Ge bonds has been synthesized via a two-step synthesis protocol. The molecular sources combine convenient handling with sufficient thermal lability to provide access to group IV alloys with low carbon content. Differences in the molecule–material conversion by chemical vapor deposition (CVD) techniques are described and traced back to the molecular design. This study illustrates the possibility of tailoring the physical and chemical properties of single-source precursors for their application in the CVD of Si1–x Ge x coatings. Moreover, partial crystallization of the Si1–x Ge x has been achieved by Ga metal-supported CVD growth, which demonstrated the potential of the presented precursor class for the synthesis of crystalline group IV alloys.

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Section: Synthesis Of CL 3 Si−ph 2 Ge−ph 2 Ge−sicl 3 (1-cl)mentioning

confidence: 99%

Mixed-Substituted Single-Source Precursors for Si_1–xGe_x Thin Film Deposition

et al. 2022

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“…[ 3,4 ] In photonics and optoelectronics, the realization of thick but pseudomorphic and Ge‐rich Si 1− x Ge x films could enable the implementation of double heterostructures [ 5 ] to advance the present, fully group‐IV‐based room temperature light‐emitting devices [ 6 ] or photodetectors. [ 7,8 ] For many of these applications, the Ge concentrations x for the thick but pseudomorphic Si 1‐x Ge x films (TPFs) should be ideally in the range between 50% and 100%, to ensure, e.g., large enough band offsets between the Si and SiGe layers. [ 5,9 ]…”

Section: Introductionmentioning

confidence: 99%

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confidence: 99%

Relaxation Delay of Ge‐Rich Epitaxial SiGe Films on Si(001)

Salomon

Aberl

Vukušić

et al. 2022

Physica Status Solidi (a)

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advance the present, fully group-IV-based room temperature light-emitting devices [6] or photodetectors. [7,8] For many of these applications, the Ge concentrations x for the thick but pseudomorphic Si 1-x Ge x films (TPFs) should be ideally in the range between 50% and 100%, to ensure, e.g., large enough band offsets between the Si and SiGe layers. [5,9] However, the literature reports mainly focus on TPFs with low Ge contents, x < 0.5, [10][11][12][13][14][15][16][17][18] with only a few exceptions for which the critical thickness for pronounced relaxation was evaluated for single Ge concentrations of about 55%. [11,17] In general, during the growth of strained epitaxial layers, the strain energy increases with the square of the misfit strain and linearly with the layer thickness. Thus, TPFs must release the inherent strain energy by either plastic or elastic relaxation above a misfit strain-dependent critical thickness (t c ). The former via the insertion of misfit dislocations, [19] the latter via an increase in surface energy, i.e., by forming 3D objects, such as surface undulations, quantum dots, or wires. [20] A general trend confirmed by this work is that for sufficiently high growth temperatures and beyond t c for flat film growth, lower misfits lead to the formation of dislocations (plastic relaxation), while for high misfits, typically 3D nanostructures form via elastic relaxation. [12,21,22] Along similar lines, a mixture of low-and high-temperature growth can be used to produce flat relaxed films, starting from low-temperature growth to favor dislocation insertion, followed by high-temperature growth to increase the film quality. [23][24][25] Equilibrium theory for t c of TPFs was first developed in the 70s [26,27] but did not consider that, in reality, the growth of TPFs, e.g., by molecular beam epitaxy (MBE), happens far from thermal equilibrium. Hence, the kinetic suppression of either dislocation nucleation or quantum dot formation at low growth temperatures (T G ) explains why for Ge concentrations x < 55% experimentally found values of t c exceed those predicted by equilibrium theory by about an order of magnitude. [11,17,[28][29][30] Along the same lines, it was shown that supersaturation in the wetting layer (WL) occurs before the nucleation of quantum dots or wires during the epitaxial deposition of pure Ge thin films. [31] However, at T G ¼ 700 °C, the supersaturation amounts to only %0.14 nm of Ge, and quantum dot formation occurs already after the deposition of 0.6 nm. [32] Notably, the onset of quantum dot formation can be accelerated or delayed by increasing or decreasing T G , respectively. [33,34]

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“…This assumption is understandable considering that the growth of 2D Ge/Si quantum wells or intermixed SiGe quantum dots on SOI has been demonstrated before. [6,25,26] However, the transfer of HWs to an SOI platform is not straightforward due to three reasons: 1) the typically increased surface roughness of SOI substrates as compared with Si bulk substrates with ultralow miscut of less than 0.05°used in the original work, [14] 2) dewetting of SOI substrates at the typical degassing temperatures, [27][28][29] and 3) the delicate window of growth parameters in which HWs form. The possibility of HW formation on SOI substrates was stated in the study by Zhang et al, [14] but details regarding related growth parameters and resulting wire lengths were not discussed there.…”

Section: Introductionmentioning

confidence: 99%

Epitaxial Growth of Planar Hutwires on Silicon‐on‐Insulator Substrates

Aberl

Vukušić

Fournel

et al. 2022

Physica Status Solidi (a)

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Quantum devices based on holes confined in crystalline Ge nanostructures have emerged as a promising platform in the field of quantum technology. Epitaxial Ge hutwires (HWs) successfully used in pioneering quantum bit (qubit) experiments are the logical next choice for long‐distance coherent spin–spin coupling experiments. However, leakage currents are currently limiting the device performance of HWs on bulk Si substrates. This drawback can be mitigated by the HW growth on silicon‐on‐insulator (SOI) substrates. Herein, molecular beam epitaxy (MBE) HW growth developed on technologically relevant SOI substrates with different device layer thicknesses is shown. Using atomic force microscopy characterization, the fabrication of HWs on SOI with lengths of up to 600 nm is demonstrated. In addition, the very narrow window of growth parameters for which successful HW growth can be achieved and the distinct differences of HW growth on SOI versus bulk Si substrates are addressed.

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SiGe quantum well infrared photodetectors on strained-silicon-on-insulator

Cited by 19 publications

References 37 publications

Mixed-Substituted Single-Source Precursors for Si_1–xGe_x Thin Film Deposition

Mixed-Substituted Single-Source Precursors for Si_1–xGe_x Thin Film Deposition

Relaxation Delay of Ge‐Rich Epitaxial SiGe Films on Si(001)

Epitaxial Growth of Planar Hutwires on Silicon‐on‐Insulator Substrates

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SiGe quantum well infrared photodetectors on strained-silicon-on-insulator

Cited by 19 publications

References 37 publications

Mixed-Substituted Single-Source Precursors for Si1–xGex Thin Film Deposition

Mixed-Substituted Single-Source Precursors for Si1–xGex Thin Film Deposition

Relaxation Delay of Ge‐Rich Epitaxial SiGe Films on Si(001)

Epitaxial Growth of Planar Hutwires on Silicon‐on‐Insulator Substrates

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Mixed-Substituted Single-Source Precursors for Si_1–xGe_x Thin Film Deposition

Mixed-Substituted Single-Source Precursors for Si_1–xGe_x Thin Film Deposition