2016
DOI: 10.1002/adfm.201603411
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Toward On‐and‐Off Magnetism: Reversible Electrochemistry to Control Magnetic Phase Transitions in Spinel Ferrites

Abstract: The magnetoelectric effect, i.e., electric-fi eld control of magnetism in artifi cial heterostructures is usually limited to surface/interface atoms of the magnetic materials. In order to attain electrical control of magnetism in bulk ferromagnets, this study proposes to extend the defi nition of magnetoelectric phenomena to include reversible, chemistry-controlled magnetization switching. A large and reversible change in the room temperature magnetization in strong ferromagnets is reported, with electrochemis… Show more

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Cited by 77 publications
(61 citation statements)
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“…The first involves non-faradaic electrostatic doping, where the charge carriers are electrostatically separated at the interface between a magnetic material and a ferroelectric78910, a dielectric11 or an electrolyte1213, in analogy to a parallel plate capacitor. The second implies faradaic electrochemical doping, where redox reactions with exchange of charge carriers14151617 occur across the interface between a magnetic material and a different chemical species, resembling the behaviour of an electrochemical cell.…”
mentioning
confidence: 99%
“…The first involves non-faradaic electrostatic doping, where the charge carriers are electrostatically separated at the interface between a magnetic material and a ferroelectric78910, a dielectric11 or an electrolyte1213, in analogy to a parallel plate capacitor. The second implies faradaic electrochemical doping, where redox reactions with exchange of charge carriers14151617 occur across the interface between a magnetic material and a different chemical species, resembling the behaviour of an electrochemical cell.…”
mentioning
confidence: 99%
“…Electric field control of magnetism has been investigated in a variety of magnetoelectric (ME) systems, including single‐phase multiferroics, composite ME heterostructures, and magnetoionics . Giant ME effects were successfully attained by applying an external voltage to modify the strain, charge, or chemical state of a magnetic component. Nonetheless, the quest for realizing a working ME device, where a high magnetic on/off ratio is accompanied with a suitable reversibility, operating voltage, switching speed, and working temperature, remains still open.…”
mentioning
confidence: 99%
“…In the past few years electrolyte gating of magnetic materials has been established as a powerful method to manipulate magnetism . Electrolytes allow for reversible modulation of appreciably higher charge carrier densities (>10 14 cm −2 ) than high‐κ dielectrics and ferroelectrics using lower voltages.…”
mentioning
confidence: 99%
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“…Besides multiferroic materials or diluted magnetic semiconductors, electrochemical setups have recently been investigated for that purpose . One can distinguish three fundamentally different processes at the electrode–electrolyte interface, which can be exploited for the electrochemical control of magnetism: I) capacitive or pseudo‐capacitive double‐layer charging, II) redox surface reactions, or III) bulk intercalation triggered by chemical reactions (magneto‐ionic effect) . As high surface‐to‐volume ratios are beneficial for all three tuning approaches, recent studies have mainly focused on ultra‐thin films and nanoporous materials …”
Section: Introductionmentioning
confidence: 99%