@article{33405, keywords = {Electrical resistivity, Magnetic field, Perovskite, Iron, Metal, Room temperature, Polarization, Electric field, Article, Chemical structure, Phase transition, Tensile strength, Temperature dependence, Electric resistance, Modulation, Concentration (composition), Electromagnetic field, Physical chemistry}, author = {Y Lee and Z.Q Liu and J.T Heron and J.D Clarkson and J Hong and C Ko and M.D Biegalski and U Aschauer and S.L Hsu and M.E Nowakowski and J Wu and H.M Christen and S Salahuddin and J.B Bokor and N.A Spaldin and D.G Schlom and Ramamoorthy Ramesh}, title = {Large resistivity modulation in mixed-phase metallic systems}, abstract = {In numerous systems, giant physical responses have been discovered when two phases coexist; for example, near a phase transition. An intermetallic FeRh system undergoes a first-order antiferromagnetic to ferromagnetic transition above room temperature and shows two-phase coexistence near the transition. Here we have investigated the effect of an electric field to FeRh/PMN-PT heterostructures and report 8% change in the electrical resistivity of FeRh films. Such a giant electroresistance (GER) response is striking in metallic systems, in which external electric fields are screened, and thus only weakly influence the carrier concentrations and mobilities. We show that our FeRh films comprise coexisting ferromagnetic and antiferromagnetic phases with different resistivities and the origin of the GER effect is the strain-mediated change in their relative proportions. The observed behaviour is reminiscent of colossal magnetoresistance in perovskite manganites and illustrates the role of mixed-phase coexistence in achieving large changes in physical properties with low-energy external perturbation. © 2015 Macmillan Publishers Limited. All rights reserved.}, year = {2015}, journal = {Nature Communications}, volume = {6}, publisher = {Nature Publishing Group}, issn = {20411723}, doi = {10.1038/ncomms6959}, note = {cited By 97}, language = {eng}, }