BiOSe: a two-dimensional high-mobility polar semiconductor with large interlayer and interfacial charge transfer

Two-dimensional semiconductors with large intrinsic polarity are highly attractive for applications in high-speed electronics, ultrafast and highly sensitive photodetectors and photocatalysis. However, previous studies mainly focus on neutral layered polar 2D materials with limited vertical dipoles...

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Veröffentlicht in:	Nanoscale 2024-08, Vol.16 (31), p.14766-14774
Hauptverfasser:	Dong, Xinyue, Hou, Yameng, Deng, Chaoyue, Wu, Jinxiong, Fu, Huixia
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creator	Dong, Xinyue Hou, Yameng Deng, Chaoyue Wu, Jinxiong Fu, Huixia
description	Two-dimensional semiconductors with large intrinsic polarity are highly attractive for applications in high-speed electronics, ultrafast and highly sensitive photodetectors and photocatalysis. However, previous studies mainly focus on neutral layered polar 2D materials with limited vertical dipoles and electrostatic potential difference (typically 0.5 e ) and almost the highest electrostatic potential difference ( Φ ) of ∼4 eV among the experimentally attainable 2D layered materials. More importantly, positioning graphene on different charged layers ([Bi 2 O 2.5 ] + or [BiSe 2 ] − ) switches the charge transfer direction, inducing selective n-doping or p-doping. Furthermore, we can use polar Bi 3 O 2.5 Se 2 as an exemplary assisted gate to gain additional holes or electrons except for the external electric field, thus breaking the traditional limitations of gate tunability (∼10 14 cm 2 ) observed in experimental settings. Our work not only expands the family of polar 2D semiconductors, but also makes a conceptual advance on using them as an assisted gate in transistors. 2D high mobility polar semiconductor Bi 3 O 2.5 Se 2 with high electrostatic potential difference, ideal as an assisted gate in high-speed electronics.
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However, previous studies mainly focus on neutral layered polar 2D materials with limited vertical dipoles and electrostatic potential difference (typically <1.5 eV). Here, using the first-principles calculations, we systematically investigated the polarity of few-layer Bi 3 O 2.5 Se 2 semiconductors with ultrahigh predicted room-temperature carrier mobility (1790 cm 2 V −1 s −1 for the monolayer). Thanks to its unique non-neutral layered structure, few-layer Bi 3 O 2.5 Se 2 contributes to a substantial interlayer charge transfer (>0.5 e ) and almost the highest electrostatic potential difference ( Φ ) of ∼4 eV among the experimentally attainable 2D layered materials. More importantly, positioning graphene on different charged layers ([Bi 2 O 2.5 ] + or [BiSe 2 ] − ) switches the charge transfer direction, inducing selective n-doping or p-doping. Furthermore, we can use polar Bi 3 O 2.5 Se 2 as an exemplary assisted gate to gain additional holes or electrons except for the external electric field, thus breaking the traditional limitations of gate tunability (∼10 14 cm 2 ) observed in experimental settings. 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title	BiOSe: a two-dimensional high-mobility polar semiconductor with large interlayer and interfacial charge transfer
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