(Invited) understanding and controlling chemo-mechanical coupling in perovskite oxides

N. H. Perry; D. Marrocchelli; S. R. Bishop; H. L. Tuller

doi:10.1149/07224.0001ecst

(Invited) understanding and controlling chemo-mechanical coupling in perovskite oxides

N. H. Perry, D. Marrocchelli, S. R. Bishop, H. L. Tuller

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

5 Citations (Scopus)

Abstract

Mixed ionic and electronic conducting perovskites that can readily exchange oxygen with the atmosphere exhibit a chemo-mechanical coupling between their oxygen content and their lattice dimensions. The lattice dilation accompanying oxygen loss, termed "chemical expansion," causes large chemical stresses in devices during operation that can lead to mechanical failure. This paper describes our work aimed at understanding, across multiple length scales, which factors impact chemical expansion coefficients in perovskites. Polycrystalline gallate and titanate perovskites containing multivalent Ni, Fe, and Co have been studied using in situ thermogravimetry, dilatometry, and diffraction to probe the chemical expansion process at macroscopic and crystal structure levels. Density functional theory, molecular dynamics, and empirical simulations have provided atomistic insight into changes taking place on the anion and cation sublattices during oxygen loss. Factors impacting the magnitude of the chemo-mechanical coupling, including oxygen vacancy radii, charge localization on cations, temperature, and crystal symmetry have been identified.

Original language	English
Title of host publication	Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2
Editors	S. R. Bishop, P. Mukherjee, Y.-T. Cheng, J. Rupp
Publisher	Electrochemical Society Inc.
Pages	1-8
Number of pages	8
Edition	24
ISBN (Electronic)	9781607687511
ISBN (Print)	9781623323936
DOIs	https://doi.org/10.1149/07224.0001ecst
Publication status	Published - 2016
Event	Symposium on Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2 - 229th ECS Meeting - San Diego, United States Duration: May 29 2016 → Jun 2 2016

Publication series

Name	ECS Transactions
Number	24
Volume	72
ISSN (Print)	1938-6737
ISSN (Electronic)	1938-5862

Other

Other	Symposium on Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2 - 229th ECS Meeting
Country/Territory	United States
City	San Diego
Period	5/29/16 → 6/2/16

All Science Journal Classification (ASJC) codes

Engineering(all)

Access to Document

10.1149/07224.0001ecst

Cite this

Perry, N. H., Marrocchelli, D., Bishop, S. R., & Tuller, H. L. (2016). (Invited) understanding and controlling chemo-mechanical coupling in perovskite oxides. In S. R. Bishop, P. Mukherjee, Y-T. Cheng, & J. Rupp (Eds.), Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2 (24 ed., pp. 1-8). (ECS Transactions; Vol. 72, No. 24). Electrochemical Society Inc.. https://doi.org/10.1149/07224.0001ecst

(Invited) understanding and controlling chemo-mechanical coupling in perovskite oxides. / Perry, N. H.; Marrocchelli, D.; Bishop, S. R. et al.
Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2. ed. / S. R. Bishop; P. Mukherjee; Y.-T. Cheng; J. Rupp. 24. ed. Electrochemical Society Inc., 2016. p. 1-8 (ECS Transactions; Vol. 72, No. 24).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Perry, NH, Marrocchelli, D, Bishop, SR & Tuller, HL 2016, (Invited) understanding and controlling chemo-mechanical coupling in perovskite oxides. in SR Bishop, P Mukherjee, Y-T Cheng & J Rupp (eds), Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2. 24 edn, ECS Transactions, no. 24, vol. 72, Electrochemical Society Inc., pp. 1-8, Symposium on Mechano-Electro-Chemical Coupling in Energy Related Materials and Devices 2 - 229th ECS Meeting, San Diego, United States, 5/29/16. https://doi.org/10.1149/07224.0001ecst

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abstract = "Mixed ionic and electronic conducting perovskites that can readily exchange oxygen with the atmosphere exhibit a chemo-mechanical coupling between their oxygen content and their lattice dimensions. The lattice dilation accompanying oxygen loss, termed {"}chemical expansion,{"} causes large chemical stresses in devices during operation that can lead to mechanical failure. This paper describes our work aimed at understanding, across multiple length scales, which factors impact chemical expansion coefficients in perovskites. Polycrystalline gallate and titanate perovskites containing multivalent Ni, Fe, and Co have been studied using in situ thermogravimetry, dilatometry, and diffraction to probe the chemical expansion process at macroscopic and crystal structure levels. Density functional theory, molecular dynamics, and empirical simulations have provided atomistic insight into changes taking place on the anion and cation sublattices during oxygen loss. Factors impacting the magnitude of the chemo-mechanical coupling, including oxygen vacancy radii, charge localization on cations, temperature, and crystal symmetry have been identified.",

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AB - Mixed ionic and electronic conducting perovskites that can readily exchange oxygen with the atmosphere exhibit a chemo-mechanical coupling between their oxygen content and their lattice dimensions. The lattice dilation accompanying oxygen loss, termed "chemical expansion," causes large chemical stresses in devices during operation that can lead to mechanical failure. This paper describes our work aimed at understanding, across multiple length scales, which factors impact chemical expansion coefficients in perovskites. Polycrystalline gallate and titanate perovskites containing multivalent Ni, Fe, and Co have been studied using in situ thermogravimetry, dilatometry, and diffraction to probe the chemical expansion process at macroscopic and crystal structure levels. Density functional theory, molecular dynamics, and empirical simulations have provided atomistic insight into changes taking place on the anion and cation sublattices during oxygen loss. Factors impacting the magnitude of the chemo-mechanical coupling, including oxygen vacancy radii, charge localization on cations, temperature, and crystal symmetry have been identified.

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(Invited) understanding and controlling chemo-mechanical coupling in perovskite oxides

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