Compressive-Strain-Facilitated Fast Oxygen Migration with Reversible Topotactic Transformation in La0.5Sr0.5CoOx via All-Solid-State Electrolyte Gating

Yin, Z. G.; Wang, Jianlin; Wang, Jing; Li, Jia; Zhou, Haihua; Zhang, Cheng; Zhang, Hui; Zhang, Jine; Shen, Fang; Hao, Jiazheng; Yu, Zibing; Gao, Yi-Hong; Wang, Yangxin; Chen, Yunzhong; Sun, J. R.; Bai, Xuedong; Wang, Jian Tao; Hu, Fengxia; Zhao, Tiesong; Shen, Baogen

doi:10.1021/acsnano.2c05243

Cited by 10 publications

(19 citation statements)

References 54 publications

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“…Ionic control of transition-metal oxides (TMOs) has become an effective pathway to tune functionalities including magnetic, − electronic, − optical, − thermoelectric, , and catalytic performances. − As the smallest ion, H + (proton) is naturally endowed with high mobility, excellent reversibility, prominent modulation effect, and broad applicability to binary and complex oxides. − In recent years, increasing efforts have been put into developing facile hydrogenation methods − and discovering novel properties in protonated phases. − Owing to the tight relationship between hydrogen (doping) concentration, lattice, and electronic structure, understanding the migration mechanism and detecting the spatial distribution of H + are necessary for finely tailoring the physical properties on a microscopic scale and enhancing the reaction efficiency of the energy-conversion process in protonic ceramic fuel cells. ,,− A typical example is the construction of reconfigurable NdNiO 3 electronic devices (artificial neurons, synapses, and memory capacitors) via the sensitivity of electronic properties to the local distribution of H + …”

Section: Introductionmentioning

confidence: 99%

Strain-Induced Uphill Hydrogen Distribution in Perovskite Oxide Films

Wang,

Gu,

Chen

et al. 2024

ACS Appl. Mater. Interfaces

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Incorporating hydrogen into transition-metal oxides (TMOs) provides a facile and powerful way to manipulate the performances of TMOs, and thus numerous efforts have been invested in developing hydrogenation methods and exploring the property modulation via hydrogen doping. However, the distribution of hydrogen ions, which is a key factor in determining the physicochemical properties on a microscopic scale, has not been clearly illustrated. Here, focusing on prototypical perovskite oxide (NdNiO 3 and La 0.67 Sr 0.33 MnO 3 ) epitaxial films, we find that hydrogen distribution exhibits an anomalous "uphill" feature (against the concentration gradient) under tensile strain, namely, the proton concentration enhances upon getting farther from the hydrogen source. Distinctly, under a compressive strain state, hydrogen shows a normal distribution without uphill features. The epitaxial strain significantly influences the chemical lattice coupling and the energy profile as a function of the hydrogen doping position, thus dominating the hydrogen distribution. Furthermore, the strain−(H + ) distribution relationship is maintained in different hydrogenation methods (metal-alkali treatment) which is first applied to perovskite oxides. The discovery of strain-dependent hydrogen distribution in oxides provides insights into tailoring the magnetoelectric and energy-conversion functionalities of TMOs via strain engineering.

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Section: Introductionmentioning

confidence: 99%

Strain-Induced Uphill Hydrogen Distribution in Perovskite Oxide Films

Wang,

Gu,

Chen

et al. 2024

ACS Appl. Mater. Interfaces

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“…Related effects have also been proposed for topotactic resistive random access memory devices. 57,58 By the above means, electrochemical gating of epitaxial films of compounds such as SrCoO 3−δ , [11][12][13][14]16,[19][20][21][24][25][26][27]31 SrCo 1−x Fe x O 3−δ , 19 and La 1−x Sr x CoO 3−δ 18,22,23,29 has been intensively studied. In terms of the structure, both ex situ and operando studies of V g -controlled P ↔ BM transformations have been performed, via transmission electron microscopy 14,21,22,24,27,29 and X-ray diffraction (XRD), [11][12][13]16,[18][19][20][21][22][23][24]27,29 significantly advancing the understanding of this (first-order 18 ) topotactic transition.…”

Section: ■ Introductionmentioning

confidence: 99%

“…In terms of the structure, both ex situ and operando studies of V g -controlled P ↔ BM transformations have been performed, via transmission electron microscopy 14,21,22,24,27,29 and X-ray diffraction (XRD), [11][12][13]16,[18][19][20][21][22][23][24]27,29 significantly advancing the understanding of this (first-order 18 ) topotactic transition. 18,56,59 Interestingly, some studies, particularly on SrCoO 3−δ , present clear evidence for tristate gating between P SrCoO 3−δ , BM SrCoO 2.5 , and hydrogenated HSrCoO 2.5 , 13,25,31 while others, particularly on La 1−x Sr x CoO 3−δ , evidence bistate gating between P and BM phases; 18,22,23,29 this difference is not yet understood. In terms of electronic transport, accompanying V g -induced metal−insulator transitions have been observed through temperature (T)-dependent resistivity (ρ) measurements, 13,18,21,23 leading to room-temperature ρ modulations up to 10 5 in SrCoO 3−δ and La 1−x Sr x CoO 3−δ .…”

Section: ■ Introductionmentioning

confidence: 99%

“…It is now understood that this can be achieved via ionic liquids and gels, − solid electrolytes, ,− and ionic conductors, ,− utilizing these media to control the insertion/extraction of various chemical species into/out of target materials they are interfaced with. These species include oxygen ions/vacancies (O/V O ), − H ions, ,− ,,,,,,, Li ions, ,, N ions, , F ions, etc., inserted/extracted into/from a variety of target materials, spanning metals, − ,,,, oxides, − ,− ...…”

Section: Introductionmentioning

confidence: 99%

“…By the above means, electrochemical gating of epitaxial films of compounds such as SrCoO 3−δ , − ,,− ,− , SrCo 1– x Fe x O 3−δ , and La 1– x Sr x CoO 3−δ ,,, has been intensively studied. In terms of the structure, both ex situ and operando studies of V g -controlled P ↔ BM transformations have been performed, via transmission electron microscopy ,,,,, and X-ray diffraction (XRD), − ,,− ,, significantly advancing the understanding of this (first-order) topotactic transition. ,, Interestingly, some studies, particularly on SrCoO 3−δ , present clear evidence for tristate gating between P SrCoO 3−δ , BM SrCoO 2.5 , and hydrogenated HSrCoO 2.5 , ,, while others, particularly on La 1– x Sr x CoO 3−δ , evidence bistate gating between P and BM phases; ,,, this difference is not yet understood.…”

Section: Introductionmentioning

confidence: 99%

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Mechanisms of Hysteresis and Reversibility across the Voltage-Driven Perovskite–Brownmillerite Transformation in Electrolyte-Gated Ultrathin La_0.5Sr_0.5CoO_3−δ

Postiglione,

Yu,

Chaturvedi

et al. 2024

ACS Appl. Mater. Interfaces

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Perovskite cobaltites have emerged as archetypes for electrochemical control of materials properties in electrolytegate devices. Voltage-driven redox cycling can be performed between fully oxygenated perovskite and oxygen-vacancy-ordered brownmillerite phases, enabling exceptional modulation of the crystal structure, electronic transport, thermal transport, magnetism, and optical properties. The vast majority of studies, however, have focused heavily on the perovskite and brownmillerite end points. In contrast, here we focus on hysteresis and reversibility across the entire perovskite ↔ brownmillerite topotactic transformation, combining gate-voltage hysteresis loops, minor hysteresis loops, quantitative operando synchrotron X-ray diffraction, and temperature-dependent (magneto)transport, on ion-gel-gated ultrathin (10-unit-cell) epitaxial La 0.5 Sr 0.5 CoO 3−δ films. Gate-voltage hysteresis loops combined with operando diffraction reveal a wealth of new mechanistic findings, including asymmetric redox kinetics due to differing oxygen diffusivities in the two phases, nonmonotonic transformation rates due to the first-order nature of the transformation, and limits on reversibility due to first-cycle structural degradation. Minor loops additionally enable the first rational design of an optimal gate-voltage cycle. Combining this knowledge, we demonstrate state-of-the-art nonvolatile cycling of electronic and magnetic properties, encompassing >10 5 transport ON/OFF ratios at room temperature, and reversible metal−insulator−metal and ferromagnet−nonferromagnet−ferromagnet cycling, all at 10-unit-cell thickness with high room-temperature stability. This paves the way for future work to establish the ultimate cycling frequency and endurance of such devices.

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Topotactic Transition: A Promising Opportunity for Creating New Oxides

Meng

Yan

Qin

et al. 2023

Adv Funct Materials

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Topotactic transition is a structural phase change in a matrix crystal lattice mediated by the ordered loss/gain and rearrangement of atoms, leading to unusual coordination environments and metal atoms with rare valent states. As early as in 1990s, low temperature hydride reduction is utilized to realize the topotactic transition. Since then, topological transformations are developed via multiple approaches. Especially, the recent discovery of the Ni‐based superconductivity in infinite‐layer nickelates has greatly boosted the topotactic transition mean to synthesizing new oxides for exploring exotic functional properties. In this review, a detailed and generalized introduction is provided to oxygen‐related topotactic transition. The main body of the review includes four parts: the structure‐facilitated effects, the mechanism of the topotactic transition, some examples of topotactic transition methods adopted in different metal oxides (V, Mn, Fe, Co, Ni) and the related applications. This study is to provide timely and thorough strategies to successfully realize topotactic transitions for researchers who are eager to create new oxide phases or new oxide materials with desired functions.

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Compressive-Strain-Facilitated Fast Oxygen Migration with Reversible Topotactic Transformation in La_0.5Sr_0.5CoO_x via All-Solid-State Electrolyte Gating

Cited by 10 publications

References 54 publications

Strain-Induced Uphill Hydrogen Distribution in Perovskite Oxide Films

Strain-Induced Uphill Hydrogen Distribution in Perovskite Oxide Films

Mechanisms of Hysteresis and Reversibility across the Voltage-Driven Perovskite–Brownmillerite Transformation in Electrolyte-Gated Ultrathin La_0.5Sr_0.5CoO_3−δ

Topotactic Transition: A Promising Opportunity for Creating New Oxides

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Compressive-Strain-Facilitated Fast Oxygen Migration with Reversible Topotactic Transformation in La0.5Sr0.5CoOx via All-Solid-State Electrolyte Gating

Cited by 10 publications

References 54 publications

Strain-Induced Uphill Hydrogen Distribution in Perovskite Oxide Films

Strain-Induced Uphill Hydrogen Distribution in Perovskite Oxide Films

Mechanisms of Hysteresis and Reversibility across the Voltage-Driven Perovskite–Brownmillerite Transformation in Electrolyte-Gated Ultrathin La0.5Sr0.5CoO3−δ

Topotactic Transition: A Promising Opportunity for Creating New Oxides

Contact Info

Product

Resources

About

Compressive-Strain-Facilitated Fast Oxygen Migration with Reversible Topotactic Transformation in La_0.5Sr_0.5CoO_x via All-Solid-State Electrolyte Gating

Mechanisms of Hysteresis and Reversibility across the Voltage-Driven Perovskite–Brownmillerite Transformation in Electrolyte-Gated Ultrathin La_0.5Sr_0.5CoO_3−δ