Doping- And Strain-Dependent Electrolyte-Gate-Induced Perovskite to Brownmillerite Transformation in Epitaxial La1- xSrxCoO3-δFilms

Vipul Chaturvedi; William M. Postiglione; Rohan D. Chakraborty; Biqiong Yu; Wojciech Tabiś; Sajna Hameed; Nikolaos Biniskos; Andrew Jacobson; Zhan Zhang; Hua Zhou; Martin Greven; Vivian E. Ferry; Chris Leighton

doi:10.1021/acsami.1c13828

Doping- And Strain-Dependent Electrolyte-Gate-Induced Perovskite to Brownmillerite Transformation in Epitaxial La_{1- x}Sr_xCoO_3-δFilms

Vipul Chaturvedi, William M. Postiglione, Rohan D. Chakraborty, Biqiong Yu, Wojciech Tabiś, Sajna Hameed, Nikolaos Biniskos, Andrew Jacobson, Zhan Zhang, Hua Zhou, Martin Greven, Vivian E. Ferry, Chris Leighton

Chemical Engineering and Materials Science

Research output: Contribution to journal › Article › peer-review

18 Scopus citations

Abstract

Much recent attention has focused on the voltage-driven reversible topotactic transformation between the ferromagnetic metallic perovskite (P) SrCoO3-δ and oxygen-vacancy-ordered antiferromagnetic insulating brownmillerite (BM) SrCoO2.5. This is emerging as a paradigmatic example of the power of electrochemical gating (using, e.g., ionic liquids/gels), the wide modulation of electronic, magnetic, and optical properties generating clear application potential. SrCoO3 films are challenging with respect to stability, however, and there has been little exploration of alternate compositions. Here, we present the first study of ion-gel-gating-induced P → BM transformations across almost the entire La1-xSrxCoO3 phase diagram (0 ≤ x ≤ 0.70), under both tensile and compressive epitaxial strain. Electronic transport, magnetometry, and operando synchrotron X-ray diffraction establish that voltage-induced P → BM transformations are possible at essentially all x, including x ≤ 0.50, where both P and BM phases are highly stable. Under small compressive strain, the transformation threshold voltage decreases from approximately +2.7 V at x = 0 to negligible at x = 0.70. Both larger compressive strain and tensile strain induce further threshold voltage lowering, particularly at low x. The P → BM threshold voltage is thus tunable, via both composition and strain. At x = 0.50, voltage-controlled ferromagnetism, transport, and optical transmittance are then demonstrated, achieving Curie temperature and resistivity modulations of ∼220 K and at least 5 orders of magnitude, respectively, and enabling estimation of the voltage-dependent Co valence. The results are analyzed in the context of doping- and strain-dependent oxygen vacancy formation energies and diffusion coefficients, establishing that it is thermodynamic factors, not kinetics, that underpin the decrease in the threshold voltage with x, that is, with increasing formal Co valence. These findings substantially advance the practical and mechanistic understanding of this voltage-driven transformation, with fundamental and technological implications.

Original language	English (US)
Pages (from-to)	51205-51217
Number of pages	13
Journal	ACS Applied Materials and Interfaces
Volume	13
Issue number	43
DOIs	https://doi.org/10.1021/acsami.1c13828
State	Published - Nov 3 2021

Bibliographical note

Funding Information:
This work was supported primarily by the National Science Foundation through the University of Minnesota MRSEC under award number DMR-2011401. Parts of this work were performed in the Characterization Facility, UMN, which receives partial support from NSF through the MRSEC and NNCI programs. Portions of this work were also conducted in the Minnesota Nano Center, which is supported by NSF through the National Nano Coordinated Infrastructure (NNCI) under ECCS-2025124. Part of this work also used resources of the Advanced Photon Source, a DOE Office of Science User Facility operated by Argonne National Laboratory under contract no. DE-AC02-06CH11357. W.T. acknowledges support from the Polish National Agency for Academic Exchange under the Polish Returns 2019 Program, grant no. PPN/PPO/2019/1/00014, and the subsidy of the Ministry of Science and Higher Education of Poland.

Publisher Copyright:
© 2021 American Chemical Society.

Keywords

cobaltites
electrolyte gating
ionic control of materials
perovskite oxides
voltage-controlled magnetism

PubMed: MeSH publication types

Journal Article

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access

10.1021/acsami.1c13828

OpenUrl availability

Full text

Cite this

Chaturvedi, V., Postiglione, W. M., Chakraborty, R. D., Yu, B., Tabiś, W., Hameed, S., Biniskos, N., Jacobson, A., Zhang, Z., Zhou, H., Greven, M., Ferry, V. E., & Leighton, C. (2021). Doping- And Strain-Dependent Electrolyte-Gate-Induced Perovskite to Brownmillerite Transformation in Epitaxial La_{1- x}Sr_xCoO_3-δFilms. ACS Applied Materials and Interfaces, 13(43), 51205-51217. https://doi.org/10.1021/acsami.1c13828

Chaturvedi, V, Postiglione, WM, Chakraborty, RD, Yu, B, Tabiś, W, Hameed, S, Biniskos, N, Jacobson, A, Zhang, Z, Zhou, H, Greven, M , Ferry, VE & Leighton, C 2021, 'Doping- And Strain-Dependent Electrolyte-Gate-Induced Perovskite to Brownmillerite Transformation in Epitaxial La_{1- x}Sr_xCoO_3-δFilms', ACS Applied Materials and Interfaces, vol. 13, no. 43, pp. 51205-51217. https://doi.org/10.1021/acsami.1c13828

@article{1437347556fc4fd7b36d8bb15f8fb04e,

title = "Doping- And Strain-Dependent Electrolyte-Gate-Induced Perovskite to Brownmillerite Transformation in Epitaxial La1- xSrxCoO3-δFilms",

abstract = "Much recent attention has focused on the voltage-driven reversible topotactic transformation between the ferromagnetic metallic perovskite (P) SrCoO3-δ and oxygen-vacancy-ordered antiferromagnetic insulating brownmillerite (BM) SrCoO2.5. This is emerging as a paradigmatic example of the power of electrochemical gating (using, e.g., ionic liquids/gels), the wide modulation of electronic, magnetic, and optical properties generating clear application potential. SrCoO3 films are challenging with respect to stability, however, and there has been little exploration of alternate compositions. Here, we present the first study of ion-gel-gating-induced P → BM transformations across almost the entire La1-xSrxCoO3 phase diagram (0 ≤ x ≤ 0.70), under both tensile and compressive epitaxial strain. Electronic transport, magnetometry, and operando synchrotron X-ray diffraction establish that voltage-induced P → BM transformations are possible at essentially all x, including x ≤ 0.50, where both P and BM phases are highly stable. Under small compressive strain, the transformation threshold voltage decreases from approximately +2.7 V at x = 0 to negligible at x = 0.70. Both larger compressive strain and tensile strain induce further threshold voltage lowering, particularly at low x. The P → BM threshold voltage is thus tunable, via both composition and strain. At x = 0.50, voltage-controlled ferromagnetism, transport, and optical transmittance are then demonstrated, achieving Curie temperature and resistivity modulations of ∼220 K and at least 5 orders of magnitude, respectively, and enabling estimation of the voltage-dependent Co valence. The results are analyzed in the context of doping- and strain-dependent oxygen vacancy formation energies and diffusion coefficients, establishing that it is thermodynamic factors, not kinetics, that underpin the decrease in the threshold voltage with x, that is, with increasing formal Co valence. These findings substantially advance the practical and mechanistic understanding of this voltage-driven transformation, with fundamental and technological implications.",

keywords = "cobaltites, electrolyte gating, ionic control of materials, perovskite oxides, voltage-controlled magnetism",

author = "Vipul Chaturvedi and Postiglione, {William M.} and Chakraborty, {Rohan D.} and Biqiong Yu and Wojciech Tabi{\'s} and Sajna Hameed and Nikolaos Biniskos and Andrew Jacobson and Zhan Zhang and Hua Zhou and Martin Greven and Ferry, {Vivian E.} and Chris Leighton",

note = "Funding Information: This work was supported primarily by the National Science Foundation through the University of Minnesota MRSEC under award number DMR-2011401. Parts of this work were performed in the Characterization Facility, UMN, which receives partial support from NSF through the MRSEC and NNCI programs. Portions of this work were also conducted in the Minnesota Nano Center, which is supported by NSF through the National Nano Coordinated Infrastructure (NNCI) under ECCS-2025124. Part of this work also used resources of the Advanced Photon Source, a DOE Office of Science User Facility operated by Argonne National Laboratory under contract no. DE-AC02-06CH11357. W.T. acknowledges support from the Polish National Agency for Academic Exchange under the Polish Returns 2019 Program, grant no. PPN/PPO/2019/1/00014, and the subsidy of the Ministry of Science and Higher Education of Poland. Publisher Copyright: {\textcopyright} 2021 American Chemical Society.",

year = "2021",

month = nov,

day = "3",

doi = "10.1021/acsami.1c13828",

language = "English (US)",

volume = "13",

pages = "51205--51217",

journal = "ACS Applied Materials and Interfaces",

issn = "1944-8244",

publisher = "American Chemical Society",

number = "43",

}

TY - JOUR

T1 - Doping- And Strain-Dependent Electrolyte-Gate-Induced Perovskite to Brownmillerite Transformation in Epitaxial La1- xSrxCoO3-δFilms

AU - Chaturvedi, Vipul

AU - Postiglione, William M.

AU - Chakraborty, Rohan D.

AU - Yu, Biqiong

AU - Tabiś, Wojciech

AU - Hameed, Sajna

AU - Biniskos, Nikolaos

AU - Jacobson, Andrew

AU - Zhang, Zhan

AU - Zhou, Hua

AU - Greven, Martin

AU - Ferry, Vivian E.

AU - Leighton, Chris

N1 - Funding Information: This work was supported primarily by the National Science Foundation through the University of Minnesota MRSEC under award number DMR-2011401. Parts of this work were performed in the Characterization Facility, UMN, which receives partial support from NSF through the MRSEC and NNCI programs. Portions of this work were also conducted in the Minnesota Nano Center, which is supported by NSF through the National Nano Coordinated Infrastructure (NNCI) under ECCS-2025124. Part of this work also used resources of the Advanced Photon Source, a DOE Office of Science User Facility operated by Argonne National Laboratory under contract no. DE-AC02-06CH11357. W.T. acknowledges support from the Polish National Agency for Academic Exchange under the Polish Returns 2019 Program, grant no. PPN/PPO/2019/1/00014, and the subsidy of the Ministry of Science and Higher Education of Poland. Publisher Copyright: © 2021 American Chemical Society.

PY - 2021/11/3

Y1 - 2021/11/3

N2 - Much recent attention has focused on the voltage-driven reversible topotactic transformation between the ferromagnetic metallic perovskite (P) SrCoO3-δ and oxygen-vacancy-ordered antiferromagnetic insulating brownmillerite (BM) SrCoO2.5. This is emerging as a paradigmatic example of the power of electrochemical gating (using, e.g., ionic liquids/gels), the wide modulation of electronic, magnetic, and optical properties generating clear application potential. SrCoO3 films are challenging with respect to stability, however, and there has been little exploration of alternate compositions. Here, we present the first study of ion-gel-gating-induced P → BM transformations across almost the entire La1-xSrxCoO3 phase diagram (0 ≤ x ≤ 0.70), under both tensile and compressive epitaxial strain. Electronic transport, magnetometry, and operando synchrotron X-ray diffraction establish that voltage-induced P → BM transformations are possible at essentially all x, including x ≤ 0.50, where both P and BM phases are highly stable. Under small compressive strain, the transformation threshold voltage decreases from approximately +2.7 V at x = 0 to negligible at x = 0.70. Both larger compressive strain and tensile strain induce further threshold voltage lowering, particularly at low x. The P → BM threshold voltage is thus tunable, via both composition and strain. At x = 0.50, voltage-controlled ferromagnetism, transport, and optical transmittance are then demonstrated, achieving Curie temperature and resistivity modulations of ∼220 K and at least 5 orders of magnitude, respectively, and enabling estimation of the voltage-dependent Co valence. The results are analyzed in the context of doping- and strain-dependent oxygen vacancy formation energies and diffusion coefficients, establishing that it is thermodynamic factors, not kinetics, that underpin the decrease in the threshold voltage with x, that is, with increasing formal Co valence. These findings substantially advance the practical and mechanistic understanding of this voltage-driven transformation, with fundamental and technological implications.

AB - Much recent attention has focused on the voltage-driven reversible topotactic transformation between the ferromagnetic metallic perovskite (P) SrCoO3-δ and oxygen-vacancy-ordered antiferromagnetic insulating brownmillerite (BM) SrCoO2.5. This is emerging as a paradigmatic example of the power of electrochemical gating (using, e.g., ionic liquids/gels), the wide modulation of electronic, magnetic, and optical properties generating clear application potential. SrCoO3 films are challenging with respect to stability, however, and there has been little exploration of alternate compositions. Here, we present the first study of ion-gel-gating-induced P → BM transformations across almost the entire La1-xSrxCoO3 phase diagram (0 ≤ x ≤ 0.70), under both tensile and compressive epitaxial strain. Electronic transport, magnetometry, and operando synchrotron X-ray diffraction establish that voltage-induced P → BM transformations are possible at essentially all x, including x ≤ 0.50, where both P and BM phases are highly stable. Under small compressive strain, the transformation threshold voltage decreases from approximately +2.7 V at x = 0 to negligible at x = 0.70. Both larger compressive strain and tensile strain induce further threshold voltage lowering, particularly at low x. The P → BM threshold voltage is thus tunable, via both composition and strain. At x = 0.50, voltage-controlled ferromagnetism, transport, and optical transmittance are then demonstrated, achieving Curie temperature and resistivity modulations of ∼220 K and at least 5 orders of magnitude, respectively, and enabling estimation of the voltage-dependent Co valence. The results are analyzed in the context of doping- and strain-dependent oxygen vacancy formation energies and diffusion coefficients, establishing that it is thermodynamic factors, not kinetics, that underpin the decrease in the threshold voltage with x, that is, with increasing formal Co valence. These findings substantially advance the practical and mechanistic understanding of this voltage-driven transformation, with fundamental and technological implications.

KW - cobaltites

KW - electrolyte gating

KW - ionic control of materials

KW - perovskite oxides

KW - voltage-controlled magnetism

UR - http://www.scopus.com/inward/record.url?scp=85118994276&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85118994276&partnerID=8YFLogxK

U2 - 10.1021/acsami.1c13828

DO - 10.1021/acsami.1c13828

M3 - Article

C2 - 34693713

AN - SCOPUS:85118994276

SN - 1944-8244

VL - 13

SP - 51205

EP - 51217

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 43

ER -