Silicene growth mechanisms on Au(111) and Au(110) substrates

Barboza, Alexandre M; da Silva-Santos, José A; Aliaga, Luis C R; Bastos, Ivan N; Faria, Daiara F

doi:10.1088/1361-6528/ad1aff

Nanotechnology

2024

DOI: 10.1088/1361-6528/ad1aff

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Silicene growth mechanisms on Au(111) and Au(110) substrates

Alexandre M Barboza,

José A da Silva-Santos,

Luis C R Aliaga

et al.

Abstract: Despite the remarkable theoretical applications of silicene, its synthesis remains a complex task, with epitaxial growth being one of the main routes involving depositing evaporated Si atoms onto a suitable substrate. Additionally, the requirement for a substrate to maintain the silicene stability poses several difficulties in accurately determining the growth mechanisms and the resulting structures, leading to conflicting results in the literature. In this study, large-scale molecular dynamics simulations are… Show more

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Cited by 2 publications

References 68 publications

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Dynamics of lithium ions on a silicene anode grown by vapor deposition using Morse and MEAM potentials

Barboza,

Aliaga,

Faria

et al. 2024

CeN

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Silicene, the silicon analogue of graphene, has been theoretically envisioned as a material with great potential applications, especially as an anode in lithium-ion batteries. However, the understanding of its behavior as an anode remains unclear, as research in this area is still in its preliminary phases. Furthermore, existing studies do not account for defects commonly found in silicene layers, which could potentially alter its behavior as an anode. Therefore, this study investigates the dynamics of Li ions on a defective silicene layer using molecular dynamics simulations and two distinct interatomic potentials: Morse and 2NN-MEAM. The results show that with both potentials, Li ions tend to position themselves in the middle of Si rings with six or more elements without significantly deforming the nearby lattice. However, the 2NN-MEAM potential causes severe deformation during Li diffusion on rings with five or less elements, making it impractical to investigate silicene as anode. In contrast, the Morse potential manages to maintain the silicene's structure. Nevertheless, during the insertion of Li ions into the anode’s channel, Si adatoms create barriers to Li diffusion, damaging the silicene structure. These results cast uncertainty upon the feasibility of employing silicene as anode.

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Dynamics of lithium ions on a silicene anode grown by vapor deposition using Morse and MEAM potentials

Barboza,

Aliaga,

Faria

et al. 2024

CeN

View full text Add to dashboard Cite

show abstract

Influence of aluminum doping on the mechanical properties of bilayer silicene

Santos,

Barboza,

Aliaga

et al. 2024

CeN

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Silicene, a two-dimensional material with potential applications in future technologies, has garnered significant interest in the past decade. Recent attention has focused on modifying silicene's electronic and magnetic properties through adatom adsorption or substitutional doping. While the magnetic, electronic, and optical properties of doped silicene have been extensively studied, a noticeable gap exists in the literature concerning its mechanical properties. In this context, this study addresses this gap by exploring the mechanical characteristics of bilayer silicene doped with aluminum by employing molecular dynamics simulations. The influence of Al concentration on the material’s mechanical response is assessed by tensile tests performed at a strain rate of 1010 s-1. The findings reveal a monotonically decreasing strength with Al concentration in both loading directions, zigzag and armchair. The deformation initiates with the rupture of Si-Al bonds, ultimately leading to a brittle fracture.

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Silicene growth mechanisms on Au(111) and Au(110) substrates

Cited by 2 publications

References 68 publications

Dynamics of lithium ions on a silicene anode grown by vapor deposition using Morse and MEAM potentials

Dynamics of lithium ions on a silicene anode grown by vapor deposition using Morse and MEAM potentials

Influence of aluminum doping on the mechanical properties of bilayer silicene

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