Dynamics of Droplet Consumption in Vapor–Liquid–Solid III–V Nanowire Growth

Pishchagin, A A; Patriarche, G.; Cattoni, Andréa; Harmand, Jean-Christophe; Oehler, Fabrice

doi:10.1021/acs.cgd.1c00504

Cited by 12 publications

(14 citation statements)

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“…Control of such structures at the ML level is actually necessary for promising applications. [44][45][46] Note that if group V sidewall diffusion contributed to droplet refill, [35] this would only require stems longer than the corresponding diffusion length, in addition to constant NW and droplet radii. [36,47] We showed that the reason for this quasideterministic growth regime is the compensation between the propagation time and preceding waiting time, expected to occur when there is never enough group V atoms in the catalyst particle to produce a full ML at nucleation.…”

Section: Discussionmentioning

confidence: 99%

“…At given temperature T, the state of the binary liquid is set by the atomic concentration x of As. The numbers of Ga and As atoms removed from the liquid to form any amount of the solid NW are equal, and we consider constant and equal rates of refilling of the droplet for Ga and As (by the direct and re-emitted beams [10,[33][34][35] and by surface diffusion, [36] which might even operate for group V species [35] ). We assume constant NW radius and droplet contact angle.…”

Section: Modelmentioning

confidence: 99%

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Statistics of Nucleation and Growth of Single Monolayers in Nanowires: Towards a Deterministic Regime

Panciera

Harmand

2022

Physica Rapid Research Ltrs

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The vapor–liquid–solid growth of semiconductor nanowires proceeds via the sequential nucleation and extension of biatomic monolayers at the interface between the solid wire and a liquid catalyst nanodroplet. In the case of III–V compounds, this mother phase contains only a small concentration of the volatile group V atoms. The growth regime where there is not enough such atoms available in the liquid at nucleation to complete a whole monolayer is studied experimentally and theoretically. Each monolayer cycle then consists in the rapid formation of a partial monolayer, followed by a slower propagation stage and by a waiting time preceding the next nucleation. The propagation and waiting times of long sequences of monolayers are measured in situ in a transmission electron microscope at three growth temperatures, in a single GaAs nanowire. The process is modeled and the statistics of the characteristic times are computed numerically and analytically. At low temperature, the weakness of group V desorption from the liquid should lead to a constant total monolayer cycle time, despite the stochasticity of the nucleation events. The modeling of the experiments yields values of several crucial growth parameters and provides guidance for the growth of nanowires in a deterministic regime.

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Section: Discussionmentioning

confidence: 99%

Section: Modelmentioning

confidence: 99%

Statistics of Nucleation and Growth of Single Monolayers in Nanowires: Towards a Deterministic Regime

Panciera

Harmand

2022

Physica Rapid Research Ltrs

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“…The predeposition time, i.e. the time during which Ga flux is on, as well as the substrate temperature, 24 determine the droplet volume. This step is crucial as the volume of the droplet is one of the determining parameters for the contact angle, defined as β , discussed later in this section.…”

Section: Electron-beam Lithographymentioning

confidence: 99%

GaAs nanowires on Si nanopillars: towards large scale, phase-engineered arrays

Güniat

Ghisalberti

Wang³

et al. 2022

Nanoscale Horiz.

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“…Ясно, однако, что диффузионная длина адатомов группы V на поверхности не может быть нулевой (в противном случае эти адатомы вообще не могли бы десорбироваться в составе димеров As 2 , P 2 или N 2 ). Недавно в работе [17] была рассмотрена диффузия адатомов P по боковой поверхности ННК GaP на расстояния до 400 nm. Вполне возможно также, что радиальный рост ННК [8,11,13,14] вне зависимости от типа катализатора или его отсутствия может контролироваться потоком элемента группы V. Целью настоящей работы является построение простой модели для скорости роста слоев III−V за счет поверхностной диффузии обоих элементов, а также установление условий, при которых рост действительно контролируется диффузией адатомов группы III.…”

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Лимитирующие Факторы Скорости Роста При Эпитаксии Полупроводниковых Соединений III-V

Дубровский¹

2023

Письма В Журнал Технической Физики

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Limiting factors for the growth rate of epitaxial III-V compound semiconductors are investigated. A model based on the two connected diffusion equations for the group III and V adatoms applies for planar layers and different nanostructures including III-V nanowires. An expression for the step growth rate is obtained and a physical parameter is revealed which determines an element which actually limits the growth process.

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Dynamics of Droplet Consumption in Vapor–Liquid–Solid III–V Nanowire Growth

Cited by 12 publications

References 50 publications

Statistics of Nucleation and Growth of Single Monolayers in Nanowires: Towards a Deterministic Regime

Statistics of Nucleation and Growth of Single Monolayers in Nanowires: Towards a Deterministic Regime

GaAs nanowires on Si nanopillars: towards large scale, phase-engineered arrays

Лимитирующие Факторы Скорости Роста При Эпитаксии Полупроводниковых Соединений III-V

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