The Fermi energy as common parameter to describe charge compensation mechanisms: A path to Fermi level engineering of oxide electroceramics

Andreas Klein; Karsten Albe; Nicole Bein; Oliver Clemens; Kim Alexander Creutz; Paul Erhart; Markus Frericks; Elaheh Ghorbani; Jan Philipp Hofmann; Binxiang Huang; Bernhard Kaiser; Ute Kolb; Jurij Koruza; Christian Kübel; Katharina N.S. Lohaus; Jürgen Rödel; Jochen Rohrer; Wolfgang Rheinheimer; Roger A. Souza; Verena Streibel; Anke Weidenkaff; Marc Widenmeyer; Bai Xiang Xu; Hongbin Zhang

doi:10.1007/s10832-023-00324-y

The Fermi energy as common parameter to describe charge compensation mechanisms: A path to Fermi level engineering of oxide electroceramics

Andreas Klein^*, Karsten Albe, Nicole Bein, Oliver Clemens, Kim Alexander Creutz, Paul Erhart, Markus Frericks, Elaheh Ghorbani, Jan Philipp Hofmann, Binxiang Huang, Bernhard Kaiser, Ute Kolb, Jurij Koruza, Christian Kübel, Katharina N.S. Lohaus, Jürgen Rödel, Jochen Rohrer, Wolfgang Rheinheimer, Roger A. Souza, Verena StreibelAnke Weidenkaff, Marc Widenmeyer, Bai Xiang Xu, Hongbin Zhang

^*Corresponding author for this work

Institute for Chemistry and Technology of Materials (6380)

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

Abstract

Chemical substitution, which can be iso- or heterovalent, is the primary strategy to tailor material properties. There are various ways how a material can react to substitution. Isovalent substitution changes the density of states while heterovalent substitution, i.e. doping, can induce electronic compensation, ionic compensation, valence changes of cations or anions, or result in the segregation or neutralization of the dopant. While all these can, in principle, occur simultaneously, it is often desirable to select a certain mechanism in order to determine material properties. Being able to predict and control the individual compensation mechanism should therefore be a key target of materials science. This contribution outlines the perspective that this could be achieved by taking the Fermi energy as a common descriptor for the different compensation mechanisms. This generalization becomes possible since the formation enthalpies of the defects involved in the various compensation mechanisms do all depend on the Fermi energy. In order to control material properties, it is then necessary to adjust the formation enthalpies and charge transition levels of the involved defects. Understanding how these depend on material composition will open up a new path for the design of materials by Fermi level engineering.

Original language	English
Pages (from-to)	147-177
Number of pages	31
Journal	Journal of Electroceramics
Volume	51
Issue number	3
DOIs	https://doi.org/10.1007/s10832-023-00324-y
Publication status	Published - Nov 2023

Keywords

Ceramic processing
Charge compensation
Defects
Electroceramics
Fermi energy
Grain boundaries
Interfaces
Oxides
Segregation
Space-charge regions
Surfaces

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Ceramics and Composites
Condensed Matter Physics
Mechanics of Materials
Materials Chemistry
Electrical and Electronic Engineering

Fields of Expertise

Advanced Materials Science

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10.1007/s10832-023-00324-yLicence: CC BY 4.0

Cite this

Klein, A., Albe, K., Bein, N., Clemens, O., Creutz, K. A., Erhart, P., Frericks, M., Ghorbani, E., Hofmann, J. P., Huang, B., Kaiser, B., Kolb, U., Koruza, J., Kübel, C., Lohaus, K. N. S., Rödel, J., Rohrer, J., Rheinheimer, W., Souza, R. A., ... Zhang, H. (2023). The Fermi energy as common parameter to describe charge compensation mechanisms: A path to Fermi level engineering of oxide electroceramics. Journal of Electroceramics, 51(3), 147-177. https://doi.org/10.1007/s10832-023-00324-y

Klein, A, Albe, K, Bein, N, Clemens, O, Creutz, KA, Erhart, P, Frericks, M, Ghorbani, E, Hofmann, JP, Huang, B, Kaiser, B, Kolb, U, Koruza, J, Kübel, C, Lohaus, KNS, Rödel, J, Rohrer, J, Rheinheimer, W, Souza, RA, Streibel, V, Weidenkaff, A, Widenmeyer, M, Xu, BX & Zhang, H 2023, 'The Fermi energy as common parameter to describe charge compensation mechanisms: A path to Fermi level engineering of oxide electroceramics', Journal of Electroceramics, vol. 51, no. 3, pp. 147-177. https://doi.org/10.1007/s10832-023-00324-y

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title = "The Fermi energy as common parameter to describe charge compensation mechanisms: A path to Fermi level engineering of oxide electroceramics",

abstract = "Chemical substitution, which can be iso- or heterovalent, is the primary strategy to tailor material properties. There are various ways how a material can react to substitution. Isovalent substitution changes the density of states while heterovalent substitution, i.e. doping, can induce electronic compensation, ionic compensation, valence changes of cations or anions, or result in the segregation or neutralization of the dopant. While all these can, in principle, occur simultaneously, it is often desirable to select a certain mechanism in order to determine material properties. Being able to predict and control the individual compensation mechanism should therefore be a key target of materials science. This contribution outlines the perspective that this could be achieved by taking the Fermi energy as a common descriptor for the different compensation mechanisms. This generalization becomes possible since the formation enthalpies of the defects involved in the various compensation mechanisms do all depend on the Fermi energy. In order to control material properties, it is then necessary to adjust the formation enthalpies and charge transition levels of the involved defects. Understanding how these depend on material composition will open up a new path for the design of materials by Fermi level engineering.",

keywords = "Ceramic processing, Charge compensation, Defects, Electroceramics, Fermi energy, Grain boundaries, Interfaces, Oxides, Segregation, Space-charge regions, Surfaces",

author = "Andreas Klein and Karsten Albe and Nicole Bein and Oliver Clemens and Creutz, {Kim Alexander} and Paul Erhart and Markus Frericks and Elaheh Ghorbani and Hofmann, {Jan Philipp} and Binxiang Huang and Bernhard Kaiser and Ute Kolb and Jurij Koruza and Christian K{\"u}bel and Lohaus, {Katharina N.S.} and J{\"u}rgen R{\"o}del and Jochen Rohrer and Wolfgang Rheinheimer and Souza, {Roger A.} and Verena Streibel and Anke Weidenkaff and Marc Widenmeyer and Xu, {Bai Xiang} and Hongbin Zhang",

note = "Publisher Copyright: {\textcopyright} 2023, The Author(s).",

year = "2023",

month = nov,

doi = "10.1007/s10832-023-00324-y",

language = "English",

volume = "51",

pages = "147--177",

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T2 - A path to Fermi level engineering of oxide electroceramics

AU - Klein, Andreas

AU - Albe, Karsten

AU - Bein, Nicole

AU - Clemens, Oliver

AU - Creutz, Kim Alexander

AU - Erhart, Paul

AU - Frericks, Markus

AU - Ghorbani, Elaheh

AU - Hofmann, Jan Philipp

AU - Huang, Binxiang

AU - Kaiser, Bernhard

AU - Kolb, Ute

AU - Koruza, Jurij

AU - Kübel, Christian

AU - Lohaus, Katharina N.S.

AU - Rödel, Jürgen

AU - Rohrer, Jochen

AU - Rheinheimer, Wolfgang

AU - Souza, Roger A.

AU - Streibel, Verena

AU - Weidenkaff, Anke

AU - Widenmeyer, Marc

AU - Xu, Bai Xiang

AU - Zhang, Hongbin

PY - 2023/11

Y1 - 2023/11

N2 - Chemical substitution, which can be iso- or heterovalent, is the primary strategy to tailor material properties. There are various ways how a material can react to substitution. Isovalent substitution changes the density of states while heterovalent substitution, i.e. doping, can induce electronic compensation, ionic compensation, valence changes of cations or anions, or result in the segregation or neutralization of the dopant. While all these can, in principle, occur simultaneously, it is often desirable to select a certain mechanism in order to determine material properties. Being able to predict and control the individual compensation mechanism should therefore be a key target of materials science. This contribution outlines the perspective that this could be achieved by taking the Fermi energy as a common descriptor for the different compensation mechanisms. This generalization becomes possible since the formation enthalpies of the defects involved in the various compensation mechanisms do all depend on the Fermi energy. In order to control material properties, it is then necessary to adjust the formation enthalpies and charge transition levels of the involved defects. Understanding how these depend on material composition will open up a new path for the design of materials by Fermi level engineering.

AB - Chemical substitution, which can be iso- or heterovalent, is the primary strategy to tailor material properties. There are various ways how a material can react to substitution. Isovalent substitution changes the density of states while heterovalent substitution, i.e. doping, can induce electronic compensation, ionic compensation, valence changes of cations or anions, or result in the segregation or neutralization of the dopant. While all these can, in principle, occur simultaneously, it is often desirable to select a certain mechanism in order to determine material properties. Being able to predict and control the individual compensation mechanism should therefore be a key target of materials science. This contribution outlines the perspective that this could be achieved by taking the Fermi energy as a common descriptor for the different compensation mechanisms. This generalization becomes possible since the formation enthalpies of the defects involved in the various compensation mechanisms do all depend on the Fermi energy. In order to control material properties, it is then necessary to adjust the formation enthalpies and charge transition levels of the involved defects. Understanding how these depend on material composition will open up a new path for the design of materials by Fermi level engineering.

KW - Ceramic processing

KW - Charge compensation

KW - Defects

KW - Electroceramics

KW - Fermi energy

KW - Grain boundaries

KW - Interfaces

KW - Oxides

KW - Segregation

KW - Space-charge regions

KW - Surfaces

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VL - 51

SP - 147

EP - 177

JO - Journal of Electroceramics

JF - Journal of Electroceramics

IS - 3

ER -

The Fermi energy as common parameter to describe charge compensation mechanisms: A path to Fermi level engineering of oxide electroceramics

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