2D ferroelectric materials: Emerging paradigms for next-generation ferroelectronics

Weijun Wang , You Meng , Wei Wang , Yuxuan Zhang , Bowen Li , Yan Yan , Boxiang Gao , Johnny C. Ho
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Abstract

Ferroelectric materials with electrically switchable spontaneous polarization are technologically important for developing next-generation low-power nanoelectronics and ferroelectronics. Regardless of significant challenges for rich functionalities owing to the insulating nature of conventional thin-film ferroelectrics, ferroelectricity instability or disappearance below a critical thickness limit generally exists. Therefore, exploring emerging two-dimensional (2D) ferroelectric materials with nanoscale dimensions and moderate bandgaps is crucial for developing high-integration functional nanoelectronics. This review offers a comprehensive analysis of the historical background and progression in both thin-film ferroelectrics and novel 2D ferroelectrics. Special attention is given to the device applications based on the emerging 2D ferroelectrics, in which the polarization switching process occurs within the channel material itself. Leveraging the switchable polarization in nanoscale 2D ferroelectrics, rationally designed device configurations with intriguing working mechanisms have been rapidly developed in various application scenarios, such as gate-tunable memristors, non-volatile memories, biological synapses, in-memory computing, etc. This review also sheds light on the potential opportunities and challenges in the future advancement of integrating novel 2D ferroelectric materials into devices within commercial electronic circuits.

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二维铁电材料:新一代铁电子学的新兴范例
具有电可开关自发极化的铁电材料对于发展下一代低功耗纳米电子学和铁电子学具有重要的技术意义。尽管由于传统薄膜铁电体的绝缘性而对丰富的功能提出了重大挑战,但铁电性不稳定或在临界厚度限制下消失通常存在。因此,探索具有纳米尺度和中等带隙的新兴二维(2D)铁电材料对于开发高集成功能纳米电子学至关重要。本文综述了薄膜铁电体和新型二维铁电体的历史背景和进展。特别关注了基于新兴的二维铁电体的器件应用,其中极化开关过程发生在通道材料本身内。利用纳米级二维铁电体的可开关极化特性,合理设计的器件结构和有趣的工作机制在门可调谐记忆电阻器、非易失性存储器、生物突触、内存计算等各种应用场景中得到了迅速发展。本综述还揭示了将新型二维铁电材料集成到商业电子电路器件中的未来发展的潜在机遇和挑战。
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