4 research outputs found
Ultrafast and low-energy switching in voltage-controlled elliptical pMTJ
Switching magnetization in a perpendicular magnetic tunnel junction (pMTJ)
via voltage controlled magnetic anisotropy (VCMA) has shown the potential to
markedly reduce the switching energy. However, the requirement of an external
magnetic field poses a critical bottleneck for its practical applications. In
this work, we propose an elliptical-shaped pMTJ to eliminate the requirement of
providing an external field by an additional circuit. We demonstrate that a 10
nm thick in-plane magnetized bias layer (BL) separated by a metallic spacer of
3 nm from the free layer (FL) can be engineered within the MTJ stack to provide
the 50 mT bias magnetic field for switching. By conducting macrospin
simulation, we find that a fast switching in 0.38 ns with energy consumption as
low as 0.3 fJ at a voltage of 1.6 V can be achieved. Furthermore, we study the
phase diagram of switching probability, showing that a pulse duration margin of
0.15 ns is obtained and a low-voltage operation (~ 1 V) is favored. Finally,
the MTJ scalability is considered, and it is found that scaling-down may not be
appealing in terms of both the energy consumption and the switching time for
the precession based VCMA switching.Comment: There are 28 pages and 5 figure
Comprehensive Scaling Analysis of Current Induced Switching in Magnetic Memories Based on In-Plane and Perpendicular Anisotropies
10.1109/JETCAS.2016.2547698IEEE JOURNAL ON EMERGING AND SELECTED TOPICS IN CIRCUITS AND SYSTEMS62120-13