Electronic and thermodynamic properties of α-Pu2O3

Yong Lu; Yu Yang; Fawei Zheng; Ping Zhang

doi:10.1016/j.physleta.2014.07.052

Electronic and thermodynamic properties of α-Pu₂O₃

Yong Lu, Yu Yang^*, Fawei Zheng, Ping Zhang

^*Corresponding author for this work

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

18 Citations (Scopus)

Abstract

Based on density functional theory+U calculations and the quasi-annealing simulation method, we obtain the ground electronic state for α-Pu₂O₃ and present its phonon dispersion curves as well as various thermodynamic properties, which have seldom been theoretically studied because of the huge unit cell. We find that the Pu-O chemical bonding is weaker in α-Pu₂O₃ than in fluorite PuO₂, and subsequently a frequency gap appears between oxygen and plutonium vibration density of states. Based on the calculated Helmholtz free energies at different temperatures, we further study the reaction energies for Pu oxidation, PuO₂ reduction, and transformation between PuO₂ and α-Pu₂O₃. Our reaction energy results are in agreements with available experiment. And it is revealed that high temperature and insufficient oxygen environment are in favor of the formation of α-Pu₂O₃.

Original language	English
Pages (from-to)	3060-3065
Number of pages	6
Journal	Physics Letters, Section A: General, Atomic and Solid State Physics
Volume	378
Issue number	41
DOIs	https://doi.org/10.1016/j.physleta.2014.07.052
Publication status	Published - 22 Aug 2014
Externally published	Yes

Keywords

First-principles calculation
Helmholtz free energy
Phonon dispersion curve
Reaction energy
α-PuO

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10.1016/j.physleta.2014.07.052

Cite this

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title = "Electronic and thermodynamic properties of α-Pu2O3",

abstract = "Based on density functional theory+U calculations and the quasi-annealing simulation method, we obtain the ground electronic state for α-Pu2O3 and present its phonon dispersion curves as well as various thermodynamic properties, which have seldom been theoretically studied because of the huge unit cell. We find that the Pu-O chemical bonding is weaker in α-Pu2O3 than in fluorite PuO2, and subsequently a frequency gap appears between oxygen and plutonium vibration density of states. Based on the calculated Helmholtz free energies at different temperatures, we further study the reaction energies for Pu oxidation, PuO2 reduction, and transformation between PuO2 and α-Pu2O3. Our reaction energy results are in agreements with available experiment. And it is revealed that high temperature and insufficient oxygen environment are in favor of the formation of α-Pu2O3.",

keywords = "First-principles calculation, Helmholtz free energy, Phonon dispersion curve, Reaction energy, α-PuO",

author = "Yong Lu and Yu Yang and Fawei Zheng and Ping Zhang",

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TY - JOUR

T1 - Electronic and thermodynamic properties of α-Pu2O3

AU - Lu, Yong

AU - Yang, Yu

AU - Zheng, Fawei

AU - Zhang, Ping

PY - 2014/8/22

Y1 - 2014/8/22

N2 - Based on density functional theory+U calculations and the quasi-annealing simulation method, we obtain the ground electronic state for α-Pu2O3 and present its phonon dispersion curves as well as various thermodynamic properties, which have seldom been theoretically studied because of the huge unit cell. We find that the Pu-O chemical bonding is weaker in α-Pu2O3 than in fluorite PuO2, and subsequently a frequency gap appears between oxygen and plutonium vibration density of states. Based on the calculated Helmholtz free energies at different temperatures, we further study the reaction energies for Pu oxidation, PuO2 reduction, and transformation between PuO2 and α-Pu2O3. Our reaction energy results are in agreements with available experiment. And it is revealed that high temperature and insufficient oxygen environment are in favor of the formation of α-Pu2O3.

AB - Based on density functional theory+U calculations and the quasi-annealing simulation method, we obtain the ground electronic state for α-Pu2O3 and present its phonon dispersion curves as well as various thermodynamic properties, which have seldom been theoretically studied because of the huge unit cell. We find that the Pu-O chemical bonding is weaker in α-Pu2O3 than in fluorite PuO2, and subsequently a frequency gap appears between oxygen and plutonium vibration density of states. Based on the calculated Helmholtz free energies at different temperatures, we further study the reaction energies for Pu oxidation, PuO2 reduction, and transformation between PuO2 and α-Pu2O3. Our reaction energy results are in agreements with available experiment. And it is revealed that high temperature and insufficient oxygen environment are in favor of the formation of α-Pu2O3.

KW - First-principles calculation

KW - Helmholtz free energy

KW - Phonon dispersion curve

KW - Reaction energy

KW - α-PuO

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JO - Physics Letters, Section A: General, Atomic and Solid State Physics

JF - Physics Letters, Section A: General, Atomic and Solid State Physics

IS - 41

ER -

Electronic and thermodynamic properties of α-Pu₂O₃

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Keywords

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