Lijia Tong , Tiantian Zhang , Lei Yue , Mengwei Yuan , Xiaoya Liu , Hongxiang Zong
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引用次数: 0
摘要
纳米电子学的进步需要具有平衡载流子迁移率和合适带隙的二维(2D)材料。本研究对二维gan - si范德华(vdW)异质结构中的本征电子和空穴迁移率进行了全面的理论分析。结果表明,其电子性能(沿y轴)优于2D GaN-ZnO、2D GaN-MoS2和2D GaN-WS2。相反,其固有空穴迁移率明显低于这些二维GaN vdW异质结构。这些发现表明,异质结构的电子特性可以通过结构工程进行选择性调谐。显著的空穴迁移率抑制,加上高电子迁移率,使2D gan - si成为一种有前途的电子传输材料,特别是能够组装具有特定传导方向(在这种情况下为y轴)的电子传输系统。
Theoretical prediction of carrier mobility in two-dimension GaN-SiS vdW heterostructure
The advancement of nanoelectronics necessitates two-dimensional (2D) materials with balanced carrier mobility and suitable bandgaps. This study presents a comprehensive theoretical analysis of the intrinsic electron and hole mobilities in 2D GaN-SiS van der Waals (vdW) heterostructure. Results reveal that its electronic performance (along the y-axis) exceeds that of 2D GaN-ZnO, 2D GaN-MoS2, and 2D GaN-WS2. Conversely, its intrinsic hole mobility is significantly lower than those of these 2D GaN vdW heterostructures. These findings demonstrate that the heterostructure's electronic properties can be selectively tuned through structural engineering. The dramatic hole mobility inhibition, coupled with high electron mobility, positions 2D GaN-SiS as a promising electron-transporting material, particularly enabling the assembly of electron-transporting systems with a specific conduction direction (the y-axis in this case).
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