The growth pattern of Ptn (n = 1–6) clusters on pentagonal B2C monolayer support: A computational study

“…A global orbital cutoff of 5.1 Å and a vacuum layer in the Z direction of 20 Å have been applied. The elected K-points are entirely similar to the previous research on penta-B 2 C nanosheet [97], with Dmol 3 code in the GGA/PBE/DNP level. Obtained optimized lattice parameters are a = b = 3.93 Å and c = 20 Å and also the angles of α = β = γ = 90 for the unit cell penta-B 2 C nanosheet, are consistent with the previous research on this nanosheet [86,[97][98][99][100].…”

“…Active positions of the penta-B 2 C are more than single B-doped carbon systems, e.g., boron doped-C 3 N 4 [89], boron doped-C 2 N [90], boron doped-graphene [91], and boron doped-CN [92]. Due to their lower symmetry, some 2D pentagonal materials display new physical and chemical virtues [87,[93][94][95][96][97]. According to the results obtained from the Li et al' studies, the penta-B 2 C nanosheet is a semiconductor with an indirect energy gap and distinguished thermal [86] and kinetically [86,98] stability.…”

“…According to the results obtained from the Li et al' studies, the penta-B 2 C nanosheet is a semiconductor with an indirect energy gap and distinguished thermal [86] and kinetically [86,98] stability. Due to the unique atomic geometries of the penta-B 2 C nanosheet, it can be proper potential applications in various fields, such as Li-/Na-ion batteries [99], desired species adsorption [97], photocatalyst [98], and so forth. [86,100] So far, no research has been conducted on the hazardous gas H 2 S' adsorption and storage on pristine penta-B 2 C surfaces.…”

Highly efficient H₂S capture using pentagonal B₂C monolayer: A periodic DFT study

“…A global orbital cutoff of 5.1 Å and a vacuum layer in the Z direction of 20 Å have been applied. The elected K-points are entirely similar to the previous research on penta-B 2 C nanosheet [97], with Dmol 3 code in the GGA/PBE/DNP level. Obtained optimized lattice parameters are a = b = 3.93 Å and c = 20 Å and also the angles of α = β = γ = 90 for the unit cell penta-B 2 C nanosheet, are consistent with the previous research on this nanosheet [86,[97][98][99][100].…”

“…Active positions of the penta-B 2 C are more than single B-doped carbon systems, e.g., boron doped-C 3 N 4 [89], boron doped-C 2 N [90], boron doped-graphene [91], and boron doped-CN [92]. Due to their lower symmetry, some 2D pentagonal materials display new physical and chemical virtues [87,[93][94][95][96][97]. According to the results obtained from the Li et al' studies, the penta-B 2 C nanosheet is a semiconductor with an indirect energy gap and distinguished thermal [86] and kinetically [86,98] stability.…”

“…According to the results obtained from the Li et al' studies, the penta-B 2 C nanosheet is a semiconductor with an indirect energy gap and distinguished thermal [86] and kinetically [86,98] stability. Due to the unique atomic geometries of the penta-B 2 C nanosheet, it can be proper potential applications in various fields, such as Li-/Na-ion batteries [99], desired species adsorption [97], photocatalyst [98], and so forth. [86,100] So far, no research has been conducted on the hazardous gas H 2 S' adsorption and storage on pristine penta-B 2 C surfaces.…”

Highly efficient H₂S capture using pentagonal B₂C monolayer: A periodic DFT study

“…Nowadays, there are many kinds of catalysts used for electrocatalytic NH 3 synthesis, among which the single-atom catalysts (SACs) has been widely concerned for their high activity and selectivity. [24][25][26][27][28][29][30] They not only have high metal loading but also greatly improve the utilization rate of metal atoms, and have been successfully applied to the NRR in recent years. However, SACs contain only single catalytic site, it is far from enough to study the SACs if the nanoscale catalyst with multiple catalytic sites is needed.…”

First‐Principles Study of 3d Transition Metal Atoms Doped Ni₁₃ Cluster as Efficient Electrocatalyst for Nitrogen Reduction Reaction

“…Graphene-based devices, including photovoltaics [ 7 ], spintronic devices [ 8 ], gas sensors [ 9 ] and graphene-based composite materials [ 10 ], have attracted wide attention in the field of two-dimensional materials owing to their excellent electronic, mechanical, photonic and thermal characters [ 11 , 12 , 13 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 , 22 ]. In addition, graphene has been proved to be a promising carrier for single-atom catalysts (SACs) due to its orbital hybridization and charge transfer between the substrate and single atoms [ 23 , 24 ].…”

Adsorption Characteristics of Gas Molecules Adsorbed on Graphene Doped with Mn: A First Principle Study