The lattice parameter – composition relationship of the body centered cubic uranium-niobium alloys

Jianzhong Zhang; Robert E. Hackenberg; Erik B. Watkins; Sven C. Vogel; Donald W. Brown

doi:10.1016/j.jnucmat.2020.152493

The lattice parameter – composition relationship of the body centered cubic uranium-niobium alloys

Jianzhong Zhang, Robert E. Hackenberg, Erik B. Watkins, Sven C. Vogel, Donald W. Brown

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

12 Scopus citations

Abstract

In-situ time-of-flight neutron diffraction experiments were performed on uranium-niobium alloy with 6 wt% Nb to study the lattice parameter-composition relationship for the body centered cubic (bcc) alloys. Based on lattice-parameter measurements of Nb-supersaturated γ_s phase over the range of 450 – 790 °C, an improved Vegard's-type relationship was established for determination of Nb concentrations at elevated temperatures. Neutron diffraction data were also collected as a function of aging time over the 450 - 600 °C range when γ_s phase decomposed isothermally into the mixture of orthorhombic α-U and Nb-rich bcc phase, as well as at room-temperature on the alloys aged ex-situ at 500 °C up to five years. From these measurements, the average Nb concentrations in the bcc phase were determined based on the Rietveld refinements of weight fraction and mass conservation relations (lever rule). Over the 15at% – 78at% range of Nb concentrations that correspond to different experimental aging times, the lattice parameters at constant temperatures exhibit a nonlinear S-shaped variation with Nb concentration, and the associated excess volumes of mixing can be described by a subregular solution model of the Redlich–Kister type of polynomial. Over the full range of composition the S-shaped deviation from Vegard's law can be modeled using a combination of an elastic continuum model and a perturbation to the radii of the solute atoms in the solvent, suggesting that electronic interactions between solute and solvent atoms could play an important role in the compositional dependence of lattice parameter for the γ-phase U-Nb alloys. While Vegard's law is a straightforward and reasonably good approximation for the bcc solid solutions in the U-Nb system, the Nb concentrations determined from the weight fraction refinements of diffraction data provide internally consistent, mass-conserving estimates of solute redistribution for the monotectoid reaction.

Original language	English
Article number	152493
Journal	Journal of Nuclear Materials
Volume	542
DOIs	https://doi.org/10.1016/j.jnucmat.2020.152493
State	Published - Dec 15 2020
Externally published	Yes

Funding

This work was supported by the US Department of Energy through the Los Alamos National Laboratory. Los Alamos National Laboratory is operated by Triad National Security, LLC, for the National Nuclear Security Administration of U.S. Department of Energy (Contract No. 89233218CNA000001 ). The research presented in this article was conducted at the Lujan Neutron Scattering Center of Los Alamos Neutron Science Center and was supported by the Science Campaign Programs and Enhanced Surveillance. This work was supported by the US Department of Energy through the Los Alamos National Laboratory. Los Alamos National Laboratory is operated by Triad National Security, LLC, for the National Nuclear Security Administration of U.S. Department of Energy (Contract No. 89233218CNA000001). The research presented in this article was conducted at the Lujan Neutron Scattering Center of Los Alamos Neutron Science Center and was supported by the Science Campaign Programs and Enhanced Surveillance.

Keywords

Continuum elasticity models
Neutron diffraction
Thermodynamics of mixing
U-Nb alloys
Vegard's law

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10.1016/j.jnucmat.2020.152493

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title = "The lattice parameter – composition relationship of the body centered cubic uranium-niobium alloys",

abstract = "In-situ time-of-flight neutron diffraction experiments were performed on uranium-niobium alloy with 6 wt\% Nb to study the lattice parameter-composition relationship for the body centered cubic (bcc) alloys. Based on lattice-parameter measurements of Nb-supersaturated γs phase over the range of 450 – 790 °C, an improved Vegard's-type relationship was established for determination of Nb concentrations at elevated temperatures. Neutron diffraction data were also collected as a function of aging time over the 450 - 600 °C range when γs phase decomposed isothermally into the mixture of orthorhombic α-U and Nb-rich bcc phase, as well as at room-temperature on the alloys aged ex-situ at 500 °C up to five years. From these measurements, the average Nb concentrations in the bcc phase were determined based on the Rietveld refinements of weight fraction and mass conservation relations (lever rule). Over the 15at\% – 78at\% range of Nb concentrations that correspond to different experimental aging times, the lattice parameters at constant temperatures exhibit a nonlinear S-shaped variation with Nb concentration, and the associated excess volumes of mixing can be described by a subregular solution model of the Redlich–Kister type of polynomial. Over the full range of composition the S-shaped deviation from Vegard's law can be modeled using a combination of an elastic continuum model and a perturbation to the radii of the solute atoms in the solvent, suggesting that electronic interactions between solute and solvent atoms could play an important role in the compositional dependence of lattice parameter for the γ-phase U-Nb alloys. While Vegard's law is a straightforward and reasonably good approximation for the bcc solid solutions in the U-Nb system, the Nb concentrations determined from the weight fraction refinements of diffraction data provide internally consistent, mass-conserving estimates of solute redistribution for the monotectoid reaction.",

keywords = "Continuum elasticity models, Neutron diffraction, Thermodynamics of mixing, U-Nb alloys, Vegard's law",

author = "Jianzhong Zhang and Hackenberg, \{Robert E.\} and Watkins, \{Erik B.\} and Vogel, \{Sven C.\} and Brown, \{Donald W.\}",

note = "Publisher Copyright: {\textcopyright} 2020",

year = "2020",

month = dec,

day = "15",

doi = "10.1016/j.jnucmat.2020.152493",

language = "English",

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T1 - The lattice parameter – composition relationship of the body centered cubic uranium-niobium alloys

AU - Zhang, Jianzhong

AU - Hackenberg, Robert E.

AU - Watkins, Erik B.

AU - Vogel, Sven C.

AU - Brown, Donald W.

PY - 2020/12/15

Y1 - 2020/12/15

N2 - In-situ time-of-flight neutron diffraction experiments were performed on uranium-niobium alloy with 6 wt% Nb to study the lattice parameter-composition relationship for the body centered cubic (bcc) alloys. Based on lattice-parameter measurements of Nb-supersaturated γs phase over the range of 450 – 790 °C, an improved Vegard's-type relationship was established for determination of Nb concentrations at elevated temperatures. Neutron diffraction data were also collected as a function of aging time over the 450 - 600 °C range when γs phase decomposed isothermally into the mixture of orthorhombic α-U and Nb-rich bcc phase, as well as at room-temperature on the alloys aged ex-situ at 500 °C up to five years. From these measurements, the average Nb concentrations in the bcc phase were determined based on the Rietveld refinements of weight fraction and mass conservation relations (lever rule). Over the 15at% – 78at% range of Nb concentrations that correspond to different experimental aging times, the lattice parameters at constant temperatures exhibit a nonlinear S-shaped variation with Nb concentration, and the associated excess volumes of mixing can be described by a subregular solution model of the Redlich–Kister type of polynomial. Over the full range of composition the S-shaped deviation from Vegard's law can be modeled using a combination of an elastic continuum model and a perturbation to the radii of the solute atoms in the solvent, suggesting that electronic interactions between solute and solvent atoms could play an important role in the compositional dependence of lattice parameter for the γ-phase U-Nb alloys. While Vegard's law is a straightforward and reasonably good approximation for the bcc solid solutions in the U-Nb system, the Nb concentrations determined from the weight fraction refinements of diffraction data provide internally consistent, mass-conserving estimates of solute redistribution for the monotectoid reaction.

AB - In-situ time-of-flight neutron diffraction experiments were performed on uranium-niobium alloy with 6 wt% Nb to study the lattice parameter-composition relationship for the body centered cubic (bcc) alloys. Based on lattice-parameter measurements of Nb-supersaturated γs phase over the range of 450 – 790 °C, an improved Vegard's-type relationship was established for determination of Nb concentrations at elevated temperatures. Neutron diffraction data were also collected as a function of aging time over the 450 - 600 °C range when γs phase decomposed isothermally into the mixture of orthorhombic α-U and Nb-rich bcc phase, as well as at room-temperature on the alloys aged ex-situ at 500 °C up to five years. From these measurements, the average Nb concentrations in the bcc phase were determined based on the Rietveld refinements of weight fraction and mass conservation relations (lever rule). Over the 15at% – 78at% range of Nb concentrations that correspond to different experimental aging times, the lattice parameters at constant temperatures exhibit a nonlinear S-shaped variation with Nb concentration, and the associated excess volumes of mixing can be described by a subregular solution model of the Redlich–Kister type of polynomial. Over the full range of composition the S-shaped deviation from Vegard's law can be modeled using a combination of an elastic continuum model and a perturbation to the radii of the solute atoms in the solvent, suggesting that electronic interactions between solute and solvent atoms could play an important role in the compositional dependence of lattice parameter for the γ-phase U-Nb alloys. While Vegard's law is a straightforward and reasonably good approximation for the bcc solid solutions in the U-Nb system, the Nb concentrations determined from the weight fraction refinements of diffraction data provide internally consistent, mass-conserving estimates of solute redistribution for the monotectoid reaction.

KW - Continuum elasticity models

KW - Neutron diffraction

KW - Thermodynamics of mixing

KW - U-Nb alloys

KW - Vegard's law

UR - https://www.scopus.com/pages/publications/85091019918

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DO - 10.1016/j.jnucmat.2020.152493

M3 - Article

AN - SCOPUS:85091019918

SN - 0022-3115

VL - 542

JO - Journal of Nuclear Materials

JF - Journal of Nuclear Materials

M1 - 152493

ER -

The lattice parameter – composition relationship of the body centered cubic uranium-niobium alloys

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