A theoretical and experimental study has uncovered new magnetic properties in two-dimensional structures, which has exciting potential for new areas of spintronics. In addition to the charge of traditional electronic devices, spintronic devices also use a quantum property called spin. Therefore, spintronics is expected to achieve ultra-high-speed and low-energy electronic devices with remarkable enhanced functions. Research by RMIT and the University of New South Wales has found that in devices consisting of several layers of novel two-dimensional materials, called vdW heterostructures, there are magnetic properties that have never been seen before.。
A theoretical and experimental study has uncovered new magnetic properties in two-dimensional structures, which has exciting potential for new areas of spintronics. In addition to the charge of traditional electronic devices, spintronic devices also use a quantum property called spin. Therefore, spintronics is expected to achieve ultra-high-speed and low-energy electronic devices with remarkable enhanced functions. Research by RMIT and the University of New South Wales has found that in devices consisting of several layers of novel two-dimensional materials, called vdW heterostructures, there are magnetic properties that have never been seen before.。
A theoretical and experimental study has uncovered new magnetic properties in two-dimensional structures, which has exciting potential for new areas of spintronics. In addition to the charge of traditional electronic devices, spintronic devices also use a quantum property called spin. Therefore, spintronics is expected to achieve ultra-high-speed and low-energy electronic devices with remarkable enhanced functions. Research by RMIT and the University of New South Wales has found that in devices consisting of several layers of novel two-dimensional materials, called vdW heterostructures, there are magnetic properties that have never been seen before.。