Electrostatic versus Electrochemical Doping and Control of Ferromagnetism in Ion-Gel-Gated Ultrathin La0.5Sr0.5CoO3−δ

Walter, Jeff; Wang, Helin; Luo, Bing; Frisbie, C. Daniel; Leighton, Chris

doi:10.1021/acsnano.6b03403

Cited by 84 publications

(147 citation statements)

References 66 publications

(184 reference statements)

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“…Similarly, ferroelectric-based modulation of T C via electrostatic manipulation of Mn valence has been demonstrated at La 1- x Sr x MnO 3 /PbZr 1- x Ti x O 3 interfaces [Vaz et al ., 2010] and linked to doping (screening) homogeneity and local structural distortions [Spurgeon et al ., 2014]. When using ionic liquids and ion gels, care must be taken to distinguish between electrostatic and electrochemical processes within the oxide layer [Jeong et al ., 2013]; recent progress has been made with this issue in specific oxides (Walter et al ., 2016), but more work is required.…”

Section: Emergent Magnetism At Interfacesmentioning

confidence: 99%

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Interface-induced phenomena in magnetism

et al. 2017

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This article reviews static and dynamic interfacial effects in magnetism, focusing on interfacially-driven magnetic effects and phenomena associated with spin-orbit coupling and intrinsic symmetry breaking at interfaces. It provides a historical background and literature survey, but focuses on recent progress, identifying the most exciting new scientific results and pointing to promising future research directions. It starts with an introduction and overview of how basic magnetic properties are affected by interfaces, then turns to a discussion of charge and spin transport through and near interfaces and how these can be used to control the properties of the magnetic layer. Important concepts include spin accumulation, spin currents, spin transfer torque, and spin pumping. An overview is provided to the current state of knowledge and existing review literature on interfacial effects such as exchange bias, exchange spring magnets, spin Hall effect, oxide heterostructures, and topological insulators. The article highlights recent discoveries of interface-induced magnetism and non-collinear spin textures, non-linear dynamics including spin torque transfer and magnetization reversal induced by interfaces, and interfacial effects in ultrafast magnetization processes.

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Section: Emergent Magnetism At Interfacesmentioning

confidence: 99%

“…Substantial further progress is anticipated in the understanding of electrostatic vs . electrochemical operation (Walter et al ., 2016), relevant length scales, associated disorder, etc . Using such methods to manipulate and harness electronic correlations is a related frontier with potential.…”

Section: Emergent Magnetism At Interfacesmentioning

confidence: 99%

Interface-induced phenomena in magnetism

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“…[49] In case of 13 nm films, the attained large values of surface charge up to 250 µC cm −2 enabled a maximum reversible modulation in magnetization of about 30% at room temperature. Several other comprehensive studies contributed to disentangle the complex relationship between charge carrier doping and magnetism in electrolyte-gated magnetic oxides, including investigations on LCMO, [80,91] LSMO, [43,156] LaMnO 3 , [67] Pr 1−x (Ca 1−y Sr y ) x MnO 3 , [157,158] LSCO, [82] Fe 3 O 4 , [159] and γ-Fe 2 O 3 . [42] In addition, the magnetic response was flexibly modulated in-phase or antiphase with respect to the induced surface charge by judiciously adjusting the applied bias voltage (see Figure 4b).…”

Section: Me Coupling Via Charge Carrier Dopingmentioning

confidence: 99%

“…Charge doping is a surface or near-surface effect, ionic migration can extend deeper into the bulk, whereas strain intervenes on a broader macroscopic scale. [49,[79][80][81][82] In this respect, the physicochemical nature of the ME interface plays a key role in determining the response of a magnetic material upon application of an external electrical stimulus. In particular, distinguishing between electrostatic and electrochemical effects is a hotly debated topic in the literature.…”

Section: Introductionmentioning

confidence: 99%

“…In particular, distinguishing between electrostatic and electrochemical effects is a hotly debated topic in the literature. [49,[79][80][81][82] In this respect, the physicochemical nature of the ME interface plays a key role in determining the response of a magnetic material upon application of an external electrical stimulus. Since the renaissance [83] of the studies on ME effect, the vast majority of research on artificial composites has focused on voltage-control of magnetism in all-solid-state ME systems.…”

Section: Introductionmentioning

confidence: 99%

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Voltage‐Control of Magnetism in All‐Solid‐State and Solid/Liquid Magnetoelectric Composites

2019

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activities. [1][2][3][4][5][6][7][8][9][10][11][12] From a technological perspective, several low-power ME applications have been envisioned, comprising devices for memory storage and processing, [13,14] tuning and filtering of RF/microwave signals, [15,16] energy conversion and harvesting, [17,18] sensing, [19,20] and actuation. [21,22] By definition, the direct ME effect is manifested when an electric polarization P is induced by usage of a magnetic field H in accordance with Δ Δ to compare the strength of the interaction between electricity and magnetism among different magnetoelectric systems. chemical control of the physical (magnetic) properties in metals and oxide nanostructures; electrostatic doping via field-effect; reversible magnetic phase transitions induced with ionic liquid charging; spintronics; printed electronics; fabrication of solution-processed devices (transistors, etc.)There are some nontrivial reasons explaining why solid/ liquid ME composites developed later than all-solid-state approaches. From an experimental perspective, the usage of conventional aqueous electrolytes poses some restrictions in terms of the operating conditions. Concerning the applied voltage, water electrolysis already occurs at a low voltage of

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Glass‐Like Through‐Plane Thermal Conductivity Induced by Oxygen Vacancies in Nanoscale Epitaxial La_0.5Sr_0.5CoO₃₋_δ

Walter

Feng

et al. 2017

Adv Funct Materials

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Ultrafast time-domain thermoreflectance (TDTR) is utilized to extract the through-plane thermal conductivity (Λ LSCO ) of epitaxial La 0.5 Sr 0.5 CoO 3−δ (LSCO) of varying thickness (<20 nm) on LaAlO 3 and SrTiO 3 substrates. These LSCO films possess ordered oxygen vacancies as the primary means of lattice mismatch accommodation with the substrate, which induces compressive/tensile strain and thus controls the orientation of the oxygen vacancy ordering (OVO). TDTR results demonstrate that the room-temperature Λ LSCO of LSCO on both substrates (1.7 W m −1 K −1 ) are nearly a factor of four lower than that of bulk single-crystal LSCO (6.2 W m −1 K −1 ). Remarkably, this approaches the lower limit of amorphous oxides (e.g., 1.3 W m −1 K −1 for glass), with no dependence on the OVO orientation. Through theoretical simulations, origins of the glass-like thermal conductivity of LSCO are revealed as a combined effect resulting from oxygen vacancies (the dominant factor), Sr substitution, size effects, and the weak electron/phonon coupling within the LSCO film. The absence of OVO dependence in the measured Λ LSCO is rationalized by two main effects: (1) the nearly isotropic phononic thermal conductivity resulting from the imperfect OVO planes when δ is small; (2) the missing electronic contribution to Λ LSCO along the through-plane direction for these ultrathin LSCO films on insulating substrates.fraction of the metals in the periodic table on either the A or B cationic site. This flexibility allows for the tuning of many functionalities by substitution of A and/ or B site cations, as well as by control of oxygen stoichiometry (i.e., by inducing oxygen vacancies or interstitials). One such example is in strontium-doped lanthanum cobaltite, La 1−x Sr x CoO 3−δ (LSCO), in which divalent Sr 2+ substitution for La 3+ hole-dopes the initially insulating and nonferromagnetic LaCoO 3 (LCO), increases the formal Co valence, and induces metallic ferromagnetism via a spin-state transition. [11] Control of the oxygen stoichiometry has been shown similarly effective in tuning the properties of LSCO. Oxygen vacancies compensate Sr-induced holes, destabilizing metallicity, and ferromagnetism, and thus controlling both. Moreover, the presence of oxygen vacancies has been shown to critically influence the high oxygen conductivity that makes LSCO an excellent candidate for gas separation membranes, [12] gas sensors, [13] and solid oxide fuel cell cathodes. [7,14] Oxygen vacancies readily form above x = 0.5 in LSCO due to the general instability of Co 4+ in octahedral coordination. [15] This is also evidenced by the very high oxygen pressure needed to form SrCoO 3 (x = 1), [16] and the tendency of SrCoO 3−δ to form Sr 2 Co 2 O 5 (SrCoO 2.5 ), the so-called Brownmillerite structure, with ordered oxygen vacancies. [17] The Brownmillerite structure is derived from perovskite when oxygen vacancies form in alternating (001) Co-O planes, along staggered [110] lines, resulting in alternating planes of tetrahedrally-and octahedrally coordinated ...

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Electrostatic versus Electrochemical Doping and Control of Ferromagnetism in Ion-Gel-Gated Ultrathin La_0.5Sr_0.5CoO_3−δ

Cited by 84 publications

References 66 publications

Interface-induced phenomena in magnetism

Interface-induced phenomena in magnetism

Voltage‐Control of Magnetism in All‐Solid‐State and Solid/Liquid Magnetoelectric Composites

Glass‐Like Through‐Plane Thermal Conductivity Induced by Oxygen Vacancies in Nanoscale Epitaxial La_0.5Sr_0.5CoO₃₋_δ

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Electrostatic versus Electrochemical Doping and Control of Ferromagnetism in Ion-Gel-Gated Ultrathin La0.5Sr0.5CoO3−δ

Cited by 84 publications

References 66 publications

Interface-induced phenomena in magnetism

Interface-induced phenomena in magnetism

Voltage‐Control of Magnetism in All‐Solid‐State and Solid/Liquid Magnetoelectric Composites

Glass‐Like Through‐Plane Thermal Conductivity Induced by Oxygen Vacancies in Nanoscale Epitaxial La0.5Sr0.5CoO3−δ

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Electrostatic versus Electrochemical Doping and Control of Ferromagnetism in Ion-Gel-Gated Ultrathin La_0.5Sr_0.5CoO_3−δ

Glass‐Like Through‐Plane Thermal Conductivity Induced by Oxygen Vacancies in Nanoscale Epitaxial La_0.5Sr_0.5CoO₃₋_δ