Voltage-driven motion of nitrogen ions: a new paradigm for magneto-ionics

Rojas, Julius de; Quintana, Alberto; Lopeandía, A. F.; Salguero, Joaquín; Muñiz, Beatriz; Ibrahim, Fatima; Chshiev, M.; Nicolenco, Aliona; Liedke, Maciej Oskar; Butterling, Maik; Wagner, A.; Sireus, Veronica; Abad, Llibertat; Jensen, Christopher; Li, Kai; Nogués, J.; Costa‐Krämer, J. L.; Menéndez, Enric; Sort, Jordi

doi:10.1038/s41467-020-19758-x

Cited by 45 publications

(77 citation statements)

References 59 publications

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“…However, such FM/reservoir bilayer systems often suffer from poor cyclability due to irreversible structural changes undergone by the FM metal in the oxidation (reduction) process, which involves the formation (destruction) of interfacial oxide phases. An alternative is the use of single-layer target materials whose crystal structure already contains the ions to be transported (such as oxygen or nitrogen) in the asprepared state (e.g., Co 3 O 4 or CoN) [8,10,24,25]. Such target materials can undergo fully reversible transformations from a nonferromagnetic (off ) to a ferromagnetic (on) state and vice versa while experiencing fewer detrimental structural changes than the previously mentioned magnetoionic approaches, possibly due to Co 3 O 4 or CoN structures providing "ready-made" lattice sites into which ions can be driven, leading to increased endurance.…”

Section: Introductionmentioning

confidence: 99%

“…Such target materials can undergo fully reversible transformations from a nonferromagnetic (off ) to a ferromagnetic (on) state and vice versa while experiencing fewer detrimental structural changes than the previously mentioned magnetoionic approaches, possibly due to Co 3 O 4 or CoN structures providing "ready-made" lattice sites into which ions can be driven, leading to increased endurance. In contrast to Co 3 O 4 , where oxygen migration is assisted by the formation of filamentary channels [10], roomtemperature on-off ferromagnetism in CoN films operates via frontlike plane-wave ionic motion at lower applied voltages and with enhanced cyclability [24]. Thus, transition metal nitrides compare favorably with their transition metal oxide counterparts for magnetoionic applications.…”

Section: Introductionmentioning

confidence: 99%

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Critical Role of Electrical Resistivity in Magnetoionics

et al. 2021

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The utility of electrical resistivity as an indicator of magnetoionic performance in stoichiometrically and structurally similar thin-film systems is demonstrated. A series of highly nanocrystalline cobalt nitride (Co-N) thin films (85 nm thick) with a broad range of electrical properties exhibit markedly different magnetoionic behaviors. Semiconducting, near stoichiometric CoN films show the best performance, better than their metallic and insulating counterparts. Resistivity reflects the interplay between atomic bonding, carrier localization, and structural defects, and in turn determines the strength and distribution of applied electric fields inside the actuated films. This fact, generally overlooked, reveals that resistivity can be used to quickly evaluate the potential of a system to exhibit optimal magnetoionic effects, while also opening interesting challenges.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Critical Role of Electrical Resistivity in Magnetoionics

et al. 2021

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“…In this regard, atomic-scale control of interfaces via ionic migration in solid-state heterostructures − as well as electrolyte-based systems ,− has emerged as an effective tool to modify materials properties, which can be further controlled by an electric field. To date, a variety of magneto-ionically controlled functionalities have been demonstrated, including magnetic anisotropy, ,, antiferromagnetism, ferromagnetism, ,,,− superconductivity, , Dzyaloshinskii–Moriya interaction, spin textures, − and so on. Many of the magneto-ionic studies have focused on the interfacial electrostatic effect, ,− where the charge build-up across interfaces under an electric field modifies the electronic structures and materials characteristics.…”

Section: Introductionmentioning

confidence: 99%

Electrically Enhanced Exchange Bias via Solid-State Magneto-ionics

Murray

Jensen

Quintana

et al. 2021

ACS Appl. Mater. Interfaces

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Electrically induced ionic motion offers a new way to realize voltage-controlled magnetism, opening the door to a new generation of logic, sensor, and data storage technologies. Here, we demonstrate an effective approach to magneto-ionically and electrically tune the exchange bias in Gd/Ni1–x Co x O thin films (x = 0.50 and 0.67), where neither of the layers alone is ferromagnetic at room temperature. The Gd capping layer deposited onto antiferromagnetic Ni1–x Co x O initiates a solid-state redox reaction that reduces an interfacial region of the oxide to ferromagnetic NiCo. An exchange bias is established after field cooling (FC), which can be enhanced by up to 35% after a voltage conditioning and subsequently reset with a second FC. These effects are caused by the presence of an interfacial ferromagnetic NiCo layer, which further alloys with the Gd layer upon FC and voltage application, as confirmed by electron microscopy and polarized neutron reflectometry studies. These results highlight the viability of the solid-state magneto-ionic approach to achieve electric control of exchange bias, with potential for energy-efficient magneto-ionic devices.

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“…Among various magnetoelectric mechanisms that allow for voltage control of magnetism, magneto‐ionics (i.e., electric‐field‐driven ion migration) has been recognized as one of the most scalable. [ 22 ] In certain semiconducting and dielectric materials, electric field induces ion migration of, for example, O 2− , [ 27–29 ] Li + , [ 30 ] H + , [ 31 ] or N 2− , [ 32 ] from the material of interest toward an ion reservoir or vice versa, depending on the voltage polarity. Diffusion of ions induces changes in the oxidation state of the metal, thus leading to large changes in magnetization.…”

Section: Introductionmentioning

confidence: 99%

“…Room‐temperature ON/OFF switching of magnetization remains rather elusive. Specifically, this has been shown in electrolyte‐gated Co 3 O 4 [ 29,35 ] and CoN [ 32 ] continuous (non‐patterned) films in which voltage was used to change the oxidation state of cobalt, taking advantage of defect‐assisted magneto‐ionics. Likewise, room‐temperature ON/OFF switching of magnetization has been realized via Li + intercalation/de‐intercalation in α‐Fe 2 O 3 nanoparticles loaded onto a Cu foil cathode in a lithium ion battery.…”

Section: Introductionmentioning

confidence: 99%

Voltage‐Induced ON Switching of Magnetism in Ordered Arrays of Non‐Ferrimagnetic Nanoporous Iron Oxide Microdisks

Cialone

Nicolenco

Robbennolt

et al. 2020

Adv Materials Inter

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Tailoring the magnetic properties of ordered arrays of patterned structures usually requires stringent control of their size, pitch, microstructure, and composition. Here, a fundamentally different approach to manipulate the magnetic behavior of lithographed microdisks, based on the application of electrical voltage, is demonstrated. First, highly porous iron oxide films with virtually no magnetic response (OFF state) are grown by sol–gel chemistry. Subsequently, arrays of microdisks (8 µm in diameter) are obtained combining lithography with wet chemical etching processes. Electrolyte‐gating (with an anhydrous electrolyte) is then employed to induce a tunable (i.e., “on‐demand”) ferromagnetic response in these disks (OFF–ON switching of magnetism) at room temperature. The changes in magnetic properties are attributed to magnetoelectrically‐driven oxygen ion migration, which is enhanced due to nanoporosity. This causes partial reduction of the oxide phases to metallic Fe. The effect can be considerably reversed by applying voltage of opposite polarity. These results are appealing for diverse technological applications that require the use of patterned structures with easily tunable magnetic properties, such as magnetic micro‐electro‐mechanical systems, microfluidic, and lab‐on‐a‐chip platforms for biomedical therapies and, ultimately, energy‐efficient magnetic memories or neuromorphic computing.

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Voltage-driven motion of nitrogen ions: a new paradigm for magneto-ionics

Cited by 45 publications

References 59 publications

Critical Role of Electrical Resistivity in Magnetoionics

Critical Role of Electrical Resistivity in Magnetoionics

Electrically Enhanced Exchange Bias via Solid-State Magneto-ionics

Voltage‐Induced ON Switching of Magnetism in Ordered Arrays of Non‐Ferrimagnetic Nanoporous Iron Oxide Microdisks

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