采用全光磁隧道结的混合自旋电子学/CMOS逻辑电路

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY IEEE Open Journal of Nanotechnology Pub Date : 2022-07-06 DOI:10.1109/OJNANO.2022.3188768
Surya Narain Dikshit;Arshid Nisar;Seema Dhull;Namita Bindal;Brajesh Kumar Kaushik
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引用次数: 2

摘要

自旋电子学是下一代低功耗、高寿命、非易失性和面积高效存储技术的新兴领域之一。自旋转矩传递(STT)、自旋轨道转矩(SOT)和电场辅助开关机制已被用于各种自旋电子器件的磁化开关。然而,它们的运行速度基本上受到自旋进动时间的限制,通常在10 - 400ps之间。这种时间限制严重限制了这些设备在高速系统中运行的可能性。另一方面,使用超短激光脉冲的光开关可以在磁隧道结(MTJs)中实现亚皮秒的开关操作。在本文中,全光开关(AOS) MTJ被用于设计高速和低功耗的基于MTJ/CMOS的混合逻辑电路,如and /NAND、XOR/XNOR和全加法器。由于AOS-MTJ的超快速开关操作,电路级结果表明,与基于STT的电路相比,基于AOS-MTJ的逻辑电路的能量和速度分别提高了85%和97%。与基于SOT的设计相比,所提出的逻辑电路在能源效率和速度方面分别提高了10%和91%。
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Hybrid Spintronics/CMOS Logic Circuits Using All-Optical-Enabled Magnetic Tunnel Junction
Spintronics is one of the emerging fields for next-generation low power, high endurance, non-volatile, and area efficient memory technology. Spin torque transfer (STT), spin orbit torque (SOT), and electric field assisted switching mechanisms have been used to switch magnetization in various spintronic devices. However, their operation speed is fundamentally limited by the spin precession time that typically ranges in 10–400 ps. Such a time constraint severely limits the possible operation of these devices in high-speed systems. Optical switching using ultrashort laser pulses, on the other hand, is able to achieve sub-picosecond switching operation in magnetic tunnel junctions (MTJs). In this paper, all optically switched (AOS) MTJ has been used to design high speed and low power hybrid MTJ/CMOS based logic circuits such as AND/NAND, XOR/XNOR, and full adder. Owing to the ultra-fast switching operation of AOS-MTJ, the circuit level results show that the energy and speed of AOS-MTJ based logic circuits are improved by 85% and 97%, respectively, when compared to STT based circuits. In comparison to SOT based designs, the proposed logic circuits show 10% and 91% improvement in energy efficiency and speed, respectively.
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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