Electronic structure of Cu2O and CuO

Jacques Ghijsen; Liu-Hao Tjeng; Jan van Elp; Henk Eskes; Jos Westerink; George A. Sawatzky; Marek T. Czyzyk

doi:10.1103/PhysRevB.38.11322

Electronic structure of Cu2O and CuO

Jacques Ghijsen, Liu-Hao Tjeng, Jan van Elp, Henk Eskes, Jos Westerink, George A. Sawatzky, Marek T. Czyzyk

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

Abstract

The electronic structure of copper oxides has been investigated by photoelectron (x-ray photoemission, ultraviolet photoemission), Auger electron, and bremsstrahlung isochromat spectroscopies. The experimental results are compared with one-electron band-structure calculations as well as with a cluster configuration interaction model. It is demonstrated that the results for Cu2O agree well with band theory, whereas those for CuO clearly show strong deviations which we argue are due to electron-correlation effects in the open-shell d bands. From the comparison to cluster calculations we extract values for the Cu d−d and O p−p Coulomb interactions, the O to Cu charge transfer energy, and the degree of Cu d−O 2p hybridization. From this we demonstrate that CuO is a charge-transfer gap insulator.

Original language	English
Pages (from-to)	11322-11330
Number of pages	9
Journal	Physical review. B, Condensed matter
Volume	38
DOIs	https://doi.org/10.1103/PhysRevB.38.11322
Publication status	Published - 1988
Externally published	Yes

Access to Document

10.1103/PhysRevB.38.11322

Cite this

@article{bd89503f39304aa6849686be56886bb6,

title = "Electronic structure of Cu2O and CuO",

abstract = "The electronic structure of copper oxides has been investigated by photoelectron (x-ray photoemission, ultraviolet photoemission), Auger electron, and bremsstrahlung isochromat spectroscopies. The experimental results are compared with one-electron band-structure calculations as well as with a cluster configuration interaction model. It is demonstrated that the results for Cu2O agree well with band theory, whereas those for CuO clearly show strong deviations which we argue are due to electron-correlation effects in the open-shell d bands. From the comparison to cluster calculations we extract values for the Cu d−d and O p−p Coulomb interactions, the O to Cu charge transfer energy, and the degree of Cu d−O 2p hybridization. From this we demonstrate that CuO is a charge-transfer gap insulator.",

author = "Jacques Ghijsen and Liu-Hao Tjeng and {van Elp}, Jan and Henk Eskes and Jos Westerink and Sawatzky, {George A.} and Czyzyk, {Marek T.}",

year = "1988",

doi = "10.1103/PhysRevB.38.11322",

language = "English",

volume = "38",

pages = "11322--11330",

journal = "Physical review. B, Condensed matter",

issn = "0163-1829",

publisher = "American institute of physics",

}

TY - JOUR

T1 - Electronic structure of Cu2O and CuO

AU - Ghijsen, Jacques

AU - Tjeng, Liu-Hao

AU - van Elp, Jan

AU - Eskes, Henk

AU - Westerink, Jos

AU - Sawatzky, George A.

AU - Czyzyk, Marek T.

PY - 1988

Y1 - 1988

N2 - The electronic structure of copper oxides has been investigated by photoelectron (x-ray photoemission, ultraviolet photoemission), Auger electron, and bremsstrahlung isochromat spectroscopies. The experimental results are compared with one-electron band-structure calculations as well as with a cluster configuration interaction model. It is demonstrated that the results for Cu2O agree well with band theory, whereas those for CuO clearly show strong deviations which we argue are due to electron-correlation effects in the open-shell d bands. From the comparison to cluster calculations we extract values for the Cu d−d and O p−p Coulomb interactions, the O to Cu charge transfer energy, and the degree of Cu d−O 2p hybridization. From this we demonstrate that CuO is a charge-transfer gap insulator.

AB - The electronic structure of copper oxides has been investigated by photoelectron (x-ray photoemission, ultraviolet photoemission), Auger electron, and bremsstrahlung isochromat spectroscopies. The experimental results are compared with one-electron band-structure calculations as well as with a cluster configuration interaction model. It is demonstrated that the results for Cu2O agree well with band theory, whereas those for CuO clearly show strong deviations which we argue are due to electron-correlation effects in the open-shell d bands. From the comparison to cluster calculations we extract values for the Cu d−d and O p−p Coulomb interactions, the O to Cu charge transfer energy, and the degree of Cu d−O 2p hybridization. From this we demonstrate that CuO is a charge-transfer gap insulator.

U2 - 10.1103/PhysRevB.38.11322

DO - 10.1103/PhysRevB.38.11322

M3 - Article

SN - 0163-1829

VL - 38

SP - 11322

EP - 11330

JO - Physical review. B, Condensed matter

JF - Physical review. B, Condensed matter

ER -

Electronic structure of Cu2O and CuO

Abstract

Access to Document

Fingerprint

Cite this