Zihan Qu, Xiaoteng Wang, Jishun Zhang, Shuo Jiang, Zuyu Xu, Fei Yang, Zuheng Wu, Yuehua Dai and Yunlai Zhu
{"title":"双层 δ-SiX (X = S/Se)† 中层间滑动诱导的反铁电-铁电-反铁电转变","authors":"Zihan Qu, Xiaoteng Wang, Jishun Zhang, Shuo Jiang, Zuyu Xu, Fei Yang, Zuheng Wu, Yuehua Dai and Yunlai Zhu","doi":"10.1039/D4TC01133C","DOIUrl":null,"url":null,"abstract":"<p >Two-dimensional (2D) sliding ferroelectric materials possess intriguing physical and electronic properties, thereby greatly expanding the family of 2D ferroelectrics (FEs). In this work, using first-principles calculations, we demonstrate a reversible antiferroelectricity–ferroelectricity–antiferroelectricity (AFE–FE–AFE) transition in bilayer δ-SiX (X = S/Se) along the in-plane direction during interlayer sliding. This transition primarily stems from the mechanical sliding of the top layer. Notably, spontaneous polarization (<em>P</em><small><sub>s</sub></small>) can reach up to approximately 80 pC m<small><sup>−1</sup></small> and 70 pC m<small><sup>−1</sup></small> for bilayers SiS and SiSe, respectively. Furthermore, the mechanism underlying this phase transition involves the interlayer between interaction energy (<em>E</em><small><sub>inter</sub></small>) and strain energy (<em>E</em><small><sub>ε</sub></small>). In the case of bilayer SiS, along the AB<small><sub>AFE</sub></small>–AA<small><sub>FE</sub></small>–AB<small><sub>AFE</sub></small> path, critical points arise from the cooperation of strain energy and mechanical sliding force. During the AC<small><sub>AFE</sub></small>–AD<small><sub>FE</sub></small> sliding process, phase transition relies on the combined effect of strain energy and mechanical sliding force. At the AD<small><sub>FE</sub></small>–AC<small><sub>AFE</sub></small> point, the transition is primarily driven by the combined action of interlayer interaction energy and mechanical sliding force. This theoretical work not only establishes a feasible approach for achieving a reversible AFE–FE–AFE phase transition, but also offers valuable insights for the design of novel volatile devices.</p>","PeriodicalId":84,"journal":{"name":"Journal of Materials Chemistry C","volume":" 36","pages":" 14387-14394"},"PeriodicalIF":5.7000,"publicationDate":"2024-07-31","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Interlayer sliding induced antiferroelectricity–ferroelectricity–antiferroelectricity transition in bilayer δ-SiX (X = S/Se)†\",\"authors\":\"Zihan Qu, Xiaoteng Wang, Jishun Zhang, Shuo Jiang, Zuyu Xu, Fei Yang, Zuheng Wu, Yuehua Dai and Yunlai Zhu\",\"doi\":\"10.1039/D4TC01133C\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p >Two-dimensional (2D) sliding ferroelectric materials possess intriguing physical and electronic properties, thereby greatly expanding the family of 2D ferroelectrics (FEs). In this work, using first-principles calculations, we demonstrate a reversible antiferroelectricity–ferroelectricity–antiferroelectricity (AFE–FE–AFE) transition in bilayer δ-SiX (X = S/Se) along the in-plane direction during interlayer sliding. This transition primarily stems from the mechanical sliding of the top layer. Notably, spontaneous polarization (<em>P</em><small><sub>s</sub></small>) can reach up to approximately 80 pC m<small><sup>−1</sup></small> and 70 pC m<small><sup>−1</sup></small> for bilayers SiS and SiSe, respectively. Furthermore, the mechanism underlying this phase transition involves the interlayer between interaction energy (<em>E</em><small><sub>inter</sub></small>) and strain energy (<em>E</em><small><sub>ε</sub></small>). In the case of bilayer SiS, along the AB<small><sub>AFE</sub></small>–AA<small><sub>FE</sub></small>–AB<small><sub>AFE</sub></small> path, critical points arise from the cooperation of strain energy and mechanical sliding force. 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Two-dimensional (2D) sliding ferroelectric materials possess intriguing physical and electronic properties, thereby greatly expanding the family of 2D ferroelectrics (FEs). In this work, using first-principles calculations, we demonstrate a reversible antiferroelectricity–ferroelectricity–antiferroelectricity (AFE–FE–AFE) transition in bilayer δ-SiX (X = S/Se) along the in-plane direction during interlayer sliding. This transition primarily stems from the mechanical sliding of the top layer. Notably, spontaneous polarization (Ps) can reach up to approximately 80 pC m−1 and 70 pC m−1 for bilayers SiS and SiSe, respectively. Furthermore, the mechanism underlying this phase transition involves the interlayer between interaction energy (Einter) and strain energy (Eε). In the case of bilayer SiS, along the ABAFE–AAFE–ABAFE path, critical points arise from the cooperation of strain energy and mechanical sliding force. During the ACAFE–ADFE sliding process, phase transition relies on the combined effect of strain energy and mechanical sliding force. At the ADFE–ACAFE point, the transition is primarily driven by the combined action of interlayer interaction energy and mechanical sliding force. This theoretical work not only establishes a feasible approach for achieving a reversible AFE–FE–AFE phase transition, but also offers valuable insights for the design of novel volatile devices.
期刊介绍:
The Journal of Materials Chemistry is divided into three distinct sections, A, B, and C, each catering to specific applications of the materials under study:
Journal of Materials Chemistry A focuses primarily on materials intended for applications in energy and sustainability.
Journal of Materials Chemistry B specializes in materials designed for applications in biology and medicine.
Journal of Materials Chemistry C is dedicated to materials suitable for applications in optical, magnetic, and electronic devices.
Example topic areas within the scope of Journal of Materials Chemistry C are listed below. This list is neither exhaustive nor exclusive.
Bioelectronics
Conductors
Detectors
Dielectrics
Displays
Ferroelectrics
Lasers
LEDs
Lighting
Liquid crystals
Memory
Metamaterials
Multiferroics
Photonics
Photovoltaics
Semiconductors
Sensors
Single molecule conductors
Spintronics
Superconductors
Thermoelectrics
Topological insulators
Transistors
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