III–V Integration on Si(100): Vertical Nanospades

Güniat, Lucas; Martí‐Sánchez, Sara; García, Oscar; Boscardin, Mégane; Vindice, David; Tappy, Nicolas; Friedl, Martin; Kim, Wonjong; Zamani, Mahdi; Francaviglia, Luca; Balgarkashi, Akshay; Leran, Jean-Baptiste; Arbiol, Jordi; Morral, Anna Fontcuberta i

doi:10.1021/acsnano.9b01546

Cited by 25 publications

(31 citation statements)

References 71 publications

(97 reference statements)

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“…To give an example, silicon nanowires could be first etched on a substrate. These could be used as templates to initiate growth of III-V nanowires on their tips and create an axial heterostructure [52,275,276]. Likewise, etched III-V nanowire structures could benefit from passivation with a subsequent radial growth of a higher bandgap material.…”

Section: Nanowire Heterostructure Formation: Growth Vs Etchingmentioning

confidence: 99%

Semiconductor nanowires: to grow or not to grow?

McIntyre

Morral

2020

Materials Today Nano

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114

122

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Semiconductor nanowires have demonstrated exciting properties for nanophotonics, sensors, energy technologies, and end-of-roadmap and beyond-roadmap electronic devices. Fabrication schemes for nanowires are varied, but they fall into three general categories: (1) top-down lithographic patterning and etching of bulk crystals and epitaxial films; (2) bottom-up, locally catalyzed crystal growth of nanowires; and (3) hybrid methods that combine aspects of categories (1) and (2). In this article, we examine the relative merits and unique attributes of each of these paradigms for nanowire synthesis. We review literature relevant to nanowire fabrication methods, faceting and dimensional control (diameter and length), positioning and alignment, doping, bulk and surface defects, and formation of unique nanowire heterostructures and metastable phases. Finally, we describe the factors governing selection among top-down, bottom-up, and hybrid methods to fabricate nanowire structures depending on their desired structural features and applications.

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Section: Nanowire Heterostructure Formation: Growth Vs Etchingmentioning

confidence: 99%

Semiconductor nanowires: to grow or not to grow?

McIntyre

Morral

2020

Materials Today Nano

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114

122

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“…61 In the presence of an APB, the growth front evolves along different angles on both sides of the boundary, which explains the formation of kinks at the surface of the nanostructure. The presence of complex APBs at the merging point between polar crystals has been also observed in complex nanostructures such as V-shape nanofins, 61 vertical nanospades 62 and close to the nucleation seed of A-polar GaAs NWs. 63 In addition, the complex defects appearing in this region also accumulate strain around them (medium-angle annular dark-field (MAADF) images revealing the accumulation of strain are shown in the ESI †).…”

Section: (C) and (D)mentioning

confidence: 79%

“…This is due to the change of polarity in the horizontal direction and is quite similar to what is observed in vertical nanospades. 62 The presence of this highly defective structure at the base of NM B is in stark contrast to the relatively defect-free region observed in NM A. The existence of these two very different crystal structures in NMs grown side-by-side underline the importance of controlling the phase and coalescence of nucleated islands to achieve defect-free crystal growth of III-Vs on Si.…”

Section: (C) and (D)mentioning

confidence: 96%

GaAs nanoscale membranes: prospects for seamless integration of III–Vs on silicon

et al. 2020

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“…Heteroepitaxial growth could be an effective method for III-V/Si integrated device fabrication, although several issues remain unsolved [4][5][6]. First, the zincblende lower symmetry of GaAs compared to the diamond one of Si (or Ge) returns the formation of antiphase domains (APD).…”

Section: Introductionmentioning

confidence: 99%

“…A careful optimization of the growth parameters [13], i.e., temperature, deposition flux, and III/V ratio, is required to exclude spurious growth on the masked regions in order to achieve perfect selectivity. Several examples of homoepitaxial growth by SAE have been reported in the literature for III-V nanostructures, such as quantum dots, nanowires, and nanomembranes [6,11,[14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Selective Area Epitaxy of GaAs/Ge/Si Nanomembranes: A Morphological Study

et al. 2020

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We demonstrate the feasibility of growing GaAs nanomembranes on a plastically-relaxed Ge layer deposited on Si (111) by exploiting selective area epitaxy in MBE. Our results are compared to the case of the GaAs homoepitaxy to highlight the criticalities arising by switching to heteroepitaxy. We found that the nanomembranes evolution strongly depends on the chosen growth parameters as well as mask pattern. The selectivity of III-V material with respect to the SiO2 mask can be obtained when the lifetime of Ga adatoms on SiO2 is reduced, so that the diffusion length of adsorbed Ga is high enough to drive the Ga adatoms towards the etched slits. The best condition for a heteroepitaxial selective area epitaxy is obtained using a growth rate equal to 0.3 ML/s of GaAs, with a As BEP pressure of about 2.5 × 10−6 torr and a temperature of 600 °C.

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III–V Integration on Si(100): Vertical Nanospades

Cited by 25 publications

References 71 publications

Semiconductor nanowires: to grow or not to grow?

Semiconductor nanowires: to grow or not to grow?

GaAs nanoscale membranes: prospects for seamless integration of III–Vs on silicon

Selective Area Epitaxy of GaAs/Ge/Si Nanomembranes: A Morphological Study

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