A first-principles study of the avalanche pressure of alpha zirconium

Qing Peng; Wei Ji; Jie Lian; Fei Gao; Shuming Peng; Hanchen Huang; Suvranu De

doi:10.1039/c6ra13752k

A first-principles study of the avalanche pressure of alpha zirconium

Qing Peng^*
, Wei Ji
, Jie Lian
, Fei Gao
, Shuming Peng
, Hanchen Huang
, Suvranu De

^*Corresponding author for this work

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

2 Scopus citations

Abstract

We investigate the stability of a monovacancy in alpha zirconium under various strains and pressures by examining the vacancy formation energy through first-principles calculations. There is a maximum formation energy of 2.35 eV under uniaxial strain corresponding to a c/a ratio of 1.75. Under volumetric strain, the formation energy increases as the strain increases. The formation energy as a function of the volumetric stress or pressure was also examined, with a minimum value of 2.00 eV at zero pressure. Using the equations of state method, we find that the formation volume of the vacancies decreases as the pressure increases, with a value of 0.6 unit-atom-volume at zero pressure. The formation enthalpy increases monotonically as the pressure increases. We predict that the avalanche pressure of alpha zirconium is -15 GPa, where vacancy formation is exothermic, causing avalanche swelling and the failure of the material.

Original language	English
Pages (from-to)	72551-72558
Number of pages	8
Journal	RSC Advances
Volume	6
Issue number	76
DOIs	https://doi.org/10.1039/c6ra13752k
State	Published - 2016
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2016 The Royal Society of Chemistry.

ASJC Scopus subject areas

General Chemistry
General Chemical Engineering

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10.1039/c6ra13752k

Cite this

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title = "A first-principles study of the avalanche pressure of alpha zirconium",

abstract = "We investigate the stability of a monovacancy in alpha zirconium under various strains and pressures by examining the vacancy formation energy through first-principles calculations. There is a maximum formation energy of 2.35 eV under uniaxial strain corresponding to a c/a ratio of 1.75. Under volumetric strain, the formation energy increases as the strain increases. The formation energy as a function of the volumetric stress or pressure was also examined, with a minimum value of 2.00 eV at zero pressure. Using the equations of state method, we find that the formation volume of the vacancies decreases as the pressure increases, with a value of 0.6 unit-atom-volume at zero pressure. The formation enthalpy increases monotonically as the pressure increases. We predict that the avalanche pressure of alpha zirconium is -15 GPa, where vacancy formation is exothermic, causing avalanche swelling and the failure of the material.",

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doi = "10.1039/c6ra13752k",

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T1 - A first-principles study of the avalanche pressure of alpha zirconium

AU - Peng, Qing

AU - Ji, Wei

AU - Lian, Jie

AU - Gao, Fei

AU - Peng, Shuming

AU - Huang, Hanchen

AU - De, Suvranu

PY - 2016

Y1 - 2016

N2 - We investigate the stability of a monovacancy in alpha zirconium under various strains and pressures by examining the vacancy formation energy through first-principles calculations. There is a maximum formation energy of 2.35 eV under uniaxial strain corresponding to a c/a ratio of 1.75. Under volumetric strain, the formation energy increases as the strain increases. The formation energy as a function of the volumetric stress or pressure was also examined, with a minimum value of 2.00 eV at zero pressure. Using the equations of state method, we find that the formation volume of the vacancies decreases as the pressure increases, with a value of 0.6 unit-atom-volume at zero pressure. The formation enthalpy increases monotonically as the pressure increases. We predict that the avalanche pressure of alpha zirconium is -15 GPa, where vacancy formation is exothermic, causing avalanche swelling and the failure of the material.

AB - We investigate the stability of a monovacancy in alpha zirconium under various strains and pressures by examining the vacancy formation energy through first-principles calculations. There is a maximum formation energy of 2.35 eV under uniaxial strain corresponding to a c/a ratio of 1.75. Under volumetric strain, the formation energy increases as the strain increases. The formation energy as a function of the volumetric stress or pressure was also examined, with a minimum value of 2.00 eV at zero pressure. Using the equations of state method, we find that the formation volume of the vacancies decreases as the pressure increases, with a value of 0.6 unit-atom-volume at zero pressure. The formation enthalpy increases monotonically as the pressure increases. We predict that the avalanche pressure of alpha zirconium is -15 GPa, where vacancy formation is exothermic, causing avalanche swelling and the failure of the material.

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DO - 10.1039/c6ra13752k

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JO - RSC Advances

JF - RSC Advances

IS - 76

ER -

A first-principles study of the avalanche pressure of alpha zirconium

Abstract

Bibliographical note

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