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★ 5.0
基于局部相变辅助细丝切换的低功耗高速Ag2S阈值开关器件
Low-Power and High-Speed Ag2S-Based Threshold Switching Device Enabled by Local Phase Transition-Assisted Filamentary Switching
| 作者 | Seongjae Heo · Sunhyeong Lee · Hyunsang Hwang |
| 期刊 | IEEE Transactions on Electron Devices |
| 出版日期 | 2025年7月 |
| 技术分类 | 电动汽车驱动 |
| 相关度评分 | ★★★★★ 5.0 / 5.0 |
| 关键词 | Ag2S阈值开关器件 低漏电流 快速开关速度 陡斜率FET应用 挥发性存储器 |
语言:
中文摘要
随着物联网(IoT)和嵌入式系统对低功耗电子设备的需求持续增长,人们对能够在低电压下以极小的泄漏电流运行,同时保持快速开关速度的新型器件的需求日益增加。为应对这一挑战,我们开发了一种基于硫化银(Ag₂S)的两端阈值开关(TS)器件,该器件在低电压下兼具低泄漏电流和快速开关速度的特性。基于Ag₂S的TS器件与金属 - 氧化物 - 半导体场效应晶体管(MOSFET)串联集成,形成了适用于陡斜率场效应晶体管(FET)应用的1T - 1S阵列。基于Ag₂S的TS器件的泄漏电流低至2 pA,与MOSFET集成后,组合式FET的亚阈值摆幅(SS)达到3 mV/十倍频。值得注意的是,该器件在2.0 V电压下的开关速度可达1 ns。此外,当Ag₂S的成分接近化学计量比时,泄漏电流和阈值电压均降低,缓解了丝状开关器件中常见的电压 - 时间困境。这些性能的提升归因于Ag₂S的局部相变以及β - Ag₂S的超离子导电性,它们有助于在电场作用下实现快速的离子传输和细丝形成。此外,在30 μA的限流电流下,该器件的关断速度可达数十纳秒。通过将限流电流提高到数百微安,该器件还表现出几分钟的短期保持特性,显示出在下一代类动态随机存取存储器(DRAM)易失性存储器中应用的潜力。
English Abstract
As the demand for low-power electronic devices in the Internet of Things (IoT) and embedded systems continues to grow, there is an increasing need for new devices that can operate at low voltages with minimal leakage current while maintaining fast switching speeds. To address this challenge, we developed a two-terminal threshold switching (TS) device based on Ag2S, demonstrating both low leakage current and fast switching speed at low voltages. The Ag2S-based TS devices were integrated in series with MOSFETs to form a 1T-1S array, designed for steep-slope FET applications. The Ag2S-based TS device exhibited a low leakage current of 2 pA, and when integrated with the MOSFET, the combined FET demonstrated a subthreshold swing (SS) of 3 mV/dec. Remarkably, the device exhibited a fast switching speed of 1 ns at 2.0 V. In addition, as the Ag2S composition approached stoichiometry, both leakage current and threshold voltage decreased, alleviating the voltage–time dilemma typically encountered in filamentary switching devices. These enhanced properties are attributed to the local phase transition of Ag2S and superionic conductivity of -Ag2S, which facilitate rapid ion transport and filament formation under an electric field. Furthermore, at a compliance current of 30~ A, the device demonstrated a turn-off speed of tens of nanoseconds. By increasing the compliance current to several hundred microamperes, the device also exhibited a short-term retention of several minutes, showing potential for application in next-generation DRAM-like volatile memory.
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SunView 深度解读
从阳光电源的业务视角来看,这项基于Ag2S的阈值开关技术虽属于微电子器件领域的基础研究,但其核心特性与我们在光伏逆变器、储能系统等产品中面临的功率控制和能效管理挑战存在潜在关联性。
该技术最突出的优势在于超低漏电流(2pA)和快速开关速度(1ns@2V),这与我们在大规模储能系统和分布式光伏应用中对功率器件的需求方向一致。当前阳光电源的储能变流器和逆变器系统中,IGBT和SiC等功率半导体器件的开关损耗和待机功耗仍是影响系统效率的关键因素。若该技术路线能够向功率级器件延伸,其亚阈值摆幅(3mV/dec)特性可能为新一代低功耗控制电路设计提供思路,特别是在物联网化的分布式能源管理系统中,数以万计的边缘控制节点对超低功耗器件有迫切需求。
然而,该技术目前仍处于实验室阶段,距离工业化应用存在明显差距。主要挑战包括:Ag2S材料在高温、高湿等光伏应用环境下的长期稳定性未经验证;器件的电流承载能力(μA级)远不能满足功率电子应用需求;制造工艺与现有半导体产线的兼容性不明确。
尽管如此,该研究揭示的局部相变辅助开关机制和超离子导电特性,为我们理解新型开关材料提供了参考。建议我们的研发团队持续跟踪此类低功耗器件技术的发展,评估其在辅助控制电路、传感器接口等低功率场景的应用可能性,为未来产品的智能化和低碳化布局储备技术洞察。