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Benefitting from its non-volatility, low power, high speed, nearly infinite endurance, good scalability and great CMOS compatibility, magnetic tunnel junction (MTJ) embedded in conventional CMOS logic circuits has been proposed as one potentially powerful solution to introduce non-volatility in today's programmable logic circuits, which is envisioned to extend the Moore's law [1].
As the CMOS technology scales down, the leakage power becomes a critical barrier for high-performance processors. In addition, the separated processor and storage units in the classic Von-Neumann architecture limit the development of advanced computer design. Spintronics is an emerging platform for nonvolatile memory and logic circuit designs [1-2]. The nonvolatility of spintronics can reduce greatly...
The Kondo effect, one of the most interesting topics in condensed matter physics, shows significant influences on the transport behaviors in magnetic tunnel junctions (MTJs).[1] As we know that there is a competition between electron tunneling and Kondo scattering in MTJs.[2] However, it is not clear how Kondo effect will affect the transport properties of a multiferroic tunnel junction (MFTJ), a...
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