Non-volatility by spin in modern nanoelectronics

Continuous miniaturization of semiconductor devices has been the main driver behind the outstanding increase of speed and performance of integrated circuits. In addition to a harmful active power penalty, small device dimensions result in rapidly rising leakages and fast growing stand-by power. The critical high power consumption becomes incompatible with the global demands to sustain and accelerate the vital industrial growth, and an introduction of new solutions for energy efficient computations becomes paramount. A highly attractive option to reduce power consumption is to introduce non-volatility in integrated circuits. Preserving the data without power eliminates the need for refreshment cycles and related leakages as well as the necessity to initialize the data in temporarily unused parts of the circuit. Spin transistors are promising devices, with the charge-based functionality complemented by the electron spin. The non-volatility is introduced by making the source and drain ferromagnetic. Recent advances in resolving several fundamental problems including spin injection from a metal ferromagnet to a semiconductor, spin propagation and relaxation, as well as spin manipulation by the electric field, resulted in successful demonstrations of such devices. However, the small relative current ratio between parallel/anti-parallel source and drain alignment at room temperature remains a substantial challenge preventing these devices from entering the market in the near future. In contrast, a magnetic tunnel junction is an excellent candidate for realizing power-reducing approaches, as it possesses a simple structure, long retention time, high endurance, fast operation speed, and yields high integration density. Magnetic tunnel junctions with large magnetoresistance ratio are perfectly suited as key elements of non-volatile magnetoresistive memory compatible with the complementary metal-oxide-semiconductor technology and capable to replace dynamic and potentially static random access memories. We review the present status of the technology, remaining challenges, as well as approaches to resolve the remaining problems. Regarding active power reduction, delegating data processing capabilities into the non-volatile segment and combining non-volatile elements with CMOS allows for efficient power gating. It also paves the way for a new low-power and high-performance computing paradigm-based on an intrinsic logic-in-memory architecture, where the same non-volatile elements are used to store and to process the information.

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