We present a multifunctional and multistate permanent memory device based on lateral electric field control of a strained surface. Sub-coercive electrical writing of a remnant strain of a PZT substrate imprints stable and rewritable resistance changes on a CoFe overlayer. A proof-of-principle device, with the simplest resistance strain gage design, is shown as a memory cell exhibiting 17-memory states of high reproducibility and reliability for nonvolatile operations. Magnetoresistance of the film also depends on the cell state, and indicates a rewritable change of magnetic properties persisting in the remnant strain of the substrate. This makes it possible to combine strain, magnetic and resistive functionalities in a single memory element, and suggests that sub-coercive stress studies are of interest for straintronics applications.
@article{arxiv.1407.3651,
title = {Multistate nonvolatile straintronics controlled by a lateral electric field},
author = {V. Iurchuk and B. Doudin and B. Kundys},
journal= {arXiv preprint arXiv:1407.3651},
year = {2014}
}
Comments
Resistive memory (RRAM) and magnetoresistive memory (MRAM) in a single device