High-temperature structure, elasticity, and thermal expansion of ε-ZrH1.8

James R. Torres; Christopher A. Mizzi; Daniel A. Rehn; Tyler Smith; Scarlett Widgeon Paisner; Adrien J. Terricabras; Darren M. Parkison; Sven C. Vogel; Caitlin A. Kohnert; Mathew L. Hayne; Thomas J. Nizolek; M. A. Torrez; Tannor T.J. Munroe; Boris Maiorov; Tarik A. Saleh; Aditya P. Shivprasad

doi:10.1016/j.jnucmat.2024.155437

High-temperature structure, elasticity, and thermal expansion of ε-ZrH_1.8

James R. Torres, Christopher A. Mizzi, Daniel A. Rehn, Tyler Smith, Scarlett Widgeon Paisner, Adrien J. Terricabras, Darren M. Parkison, Sven C. Vogel, Caitlin A. Kohnert, Mathew L. Hayne, Thomas J. Nizolek, M. A. Torrez, Tannor T.J. Munroe, Boris Maiorov, Tarik A. Saleh, Aditya P. Shivprasad

Materials Engineering

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

2 Scopus citations

Abstract

Zirconium hydride is a promising candidate material for nuclear microreactor applications as a solid-state moderator component, owing to its favorable neutronics properties and good thermal stability over other metal hydrides. In the present work, the crystal structure, thermal expansion, and elastic properties of the hydrogen-rich ε phase hydride were measured at elevated temperatures in the range 300–900 K. Samples were prepared by direct hydriding Zircaloy-4 metal – a nuclear-grade zirconium alloy. Room-temperature lattice parameters agree well with those reported from literature for unalloyed zirconium hydride and fall within an observed quadratic H-content dependence. The coefficients of thermal expansion, determined from lattice expansion and dilatometry, agree well within our work but were about 30 % lower than those reported by others for unalloyed hydrides. Density functional theory-based molecular dynamics simulations were used to compare with thermal expansion and elasticity measurements. Results showed lattice parameter temperature dependence and slope of thermal expansion align with those from measurements. Based on diffraction scans at select temperatures, ε phase remained stable in air up to at least 770 K. Likewise, dilatometry showed smooth thermal expansion up to the thermal decomposition temperature around 950 K. The precise decomposition temperature was not determined via diffraction due to sparse scanning. The complete elastic property measurements were gathered for ε-phase Ziracloy-4 hydride for the first time. Young's modulus was lower compared to the metal and δ hydride phases. High-temperature elasticity measurements were limited to <350 K due to acoustic dissipation effects.

Original language	English
Article number	155437
Journal	Journal of Nuclear Materials
Volume	603
DOIs	https://doi.org/10.1016/j.jnucmat.2024.155437
State	Published - Jan 2025

Funding

This work was supported by NASA's Space Technology Mission Directorate (STMD) through the Space Nuclear Propulsion (SNP) project. This work was performed, in part, at the Los Alamos Neutron Science Center (LANSCE), a NNSA User Facility operated for the U.S. Department of Energy (DOE) by Los Alamos National Laboratory (Contract No. 89233218CNA000001 ). We acknowledge the support by the Institutional Computing Program at LANL, via the Center for Integrated Nanotechnologies, a DOE BES user facility, for computational resources. A portion of this research used resources at the High Flux Isotope Reactor, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. This work was supported by NASA's Space Technology Mission Directorate (STMD) through the Space Nuclear Propulsion (SNP) project. This work was performed, in part, at the Los Alamos Neutron Science Center (LANSCE), a NNSA User Facility operated for the U.S. Department of Energy (DOE) by Los Alamos National Laboratory (Contract No 89233218CNA000001). We acknowledge the support by the Institutional Computing Program at LANL, via the Center for Integrated Nanotechnologies, a DOE BES user facility, for computational resources. A portion of this research used resources at the High Flux Isotope Reactor, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. This manuscript has been authored by UT-Battelle LLC under Contract No. DE-AC05-00OR22725 with the U.S. Department of Energy. The United States Government retains and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non-exclusive, paid-up, irrevocable, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes. The Department of Energy will provide public access to these results of federally sponsored research in accordance with the DOE Public Access Plan ( http://energy.gov/downloads/doe-public-access-plan ).

Keywords

Crystal structure
Elasticity
Metal hydrides
Neutron diffraction
Thermal expansion
Ultrasonics

Access to Document

10.1016/j.jnucmat.2024.155437

Cite this

Torres, J. R., Mizzi, C. A., Rehn, D. A., Smith, T., Paisner, S. W., Terricabras, A. J., Parkison, D. M., Vogel, S. C., Kohnert, C. A., Hayne, M. L., Nizolek, T. J., Torrez, M. A., Munroe, T. T. J., Maiorov, B., Saleh, T. A., & Shivprasad, A. P. (2025). High-temperature structure, elasticity, and thermal expansion of ε-ZrH_1.8. Journal of Nuclear Materials, 603, Article 155437. https://doi.org/10.1016/j.jnucmat.2024.155437

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title = "High-temperature structure, elasticity, and thermal expansion of ε-ZrH1.8",

abstract = "Zirconium hydride is a promising candidate material for nuclear microreactor applications as a solid-state moderator component, owing to its favorable neutronics properties and good thermal stability over other metal hydrides. In the present work, the crystal structure, thermal expansion, and elastic properties of the hydrogen-rich ε phase hydride were measured at elevated temperatures in the range 300–900 K. Samples were prepared by direct hydriding Zircaloy-4 metal – a nuclear-grade zirconium alloy. Room-temperature lattice parameters agree well with those reported from literature for unalloyed zirconium hydride and fall within an observed quadratic H-content dependence. The coefficients of thermal expansion, determined from lattice expansion and dilatometry, agree well within our work but were about 30 % lower than those reported by others for unalloyed hydrides. Density functional theory-based molecular dynamics simulations were used to compare with thermal expansion and elasticity measurements. Results showed lattice parameter temperature dependence and slope of thermal expansion align with those from measurements. Based on diffraction scans at select temperatures, ε phase remained stable in air up to at least 770 K. Likewise, dilatometry showed smooth thermal expansion up to the thermal decomposition temperature around 950 K. The precise decomposition temperature was not determined via diffraction due to sparse scanning. The complete elastic property measurements were gathered for ε-phase Ziracloy-4 hydride for the first time. Young's modulus was lower compared to the metal and δ hydride phases. High-temperature elasticity measurements were limited to <350 K due to acoustic dissipation effects.",

keywords = "Crystal structure, Elasticity, Metal hydrides, Neutron diffraction, Thermal expansion, Ultrasonics",

author = "Torres, {James R.} and Mizzi, {Christopher A.} and Rehn, {Daniel A.} and Tyler Smith and Paisner, {Scarlett Widgeon} and Terricabras, {Adrien J.} and Parkison, {Darren M.} and Vogel, {Sven C.} and Kohnert, {Caitlin A.} and Hayne, {Mathew L.} and Nizolek, {Thomas J.} and Torrez, {M. A.} and Munroe, {Tannor T.J.} and Boris Maiorov and Saleh, {Tarik A.} and Shivprasad, {Aditya P.}",

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doi = "10.1016/j.jnucmat.2024.155437",

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Torres, JR, Mizzi, CA, Rehn, DA, Smith, T, Paisner, SW, Terricabras, AJ, Parkison, DM, Vogel, SC, Kohnert, CA, Hayne, ML, Nizolek, TJ, Torrez, MA, Munroe, TTJ, Maiorov, B, Saleh, TA & Shivprasad, AP 2025, 'High-temperature structure, elasticity, and thermal expansion of ε-ZrH_1.8', Journal of Nuclear Materials, vol. 603, 155437. https://doi.org/10.1016/j.jnucmat.2024.155437

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AU - Paisner, Scarlett Widgeon

AU - Terricabras, Adrien J.

AU - Parkison, Darren M.

AU - Vogel, Sven C.

AU - Kohnert, Caitlin A.

AU - Hayne, Mathew L.

AU - Nizolek, Thomas J.

AU - Torrez, M. A.

AU - Munroe, Tannor T.J.

AU - Maiorov, Boris

AU - Saleh, Tarik A.

AU - Shivprasad, Aditya P.

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N2 - Zirconium hydride is a promising candidate material for nuclear microreactor applications as a solid-state moderator component, owing to its favorable neutronics properties and good thermal stability over other metal hydrides. In the present work, the crystal structure, thermal expansion, and elastic properties of the hydrogen-rich ε phase hydride were measured at elevated temperatures in the range 300–900 K. Samples were prepared by direct hydriding Zircaloy-4 metal – a nuclear-grade zirconium alloy. Room-temperature lattice parameters agree well with those reported from literature for unalloyed zirconium hydride and fall within an observed quadratic H-content dependence. The coefficients of thermal expansion, determined from lattice expansion and dilatometry, agree well within our work but were about 30 % lower than those reported by others for unalloyed hydrides. Density functional theory-based molecular dynamics simulations were used to compare with thermal expansion and elasticity measurements. Results showed lattice parameter temperature dependence and slope of thermal expansion align with those from measurements. Based on diffraction scans at select temperatures, ε phase remained stable in air up to at least 770 K. Likewise, dilatometry showed smooth thermal expansion up to the thermal decomposition temperature around 950 K. The precise decomposition temperature was not determined via diffraction due to sparse scanning. The complete elastic property measurements were gathered for ε-phase Ziracloy-4 hydride for the first time. Young's modulus was lower compared to the metal and δ hydride phases. High-temperature elasticity measurements were limited to <350 K due to acoustic dissipation effects.

AB - Zirconium hydride is a promising candidate material for nuclear microreactor applications as a solid-state moderator component, owing to its favorable neutronics properties and good thermal stability over other metal hydrides. In the present work, the crystal structure, thermal expansion, and elastic properties of the hydrogen-rich ε phase hydride were measured at elevated temperatures in the range 300–900 K. Samples were prepared by direct hydriding Zircaloy-4 metal – a nuclear-grade zirconium alloy. Room-temperature lattice parameters agree well with those reported from literature for unalloyed zirconium hydride and fall within an observed quadratic H-content dependence. The coefficients of thermal expansion, determined from lattice expansion and dilatometry, agree well within our work but were about 30 % lower than those reported by others for unalloyed hydrides. Density functional theory-based molecular dynamics simulations were used to compare with thermal expansion and elasticity measurements. Results showed lattice parameter temperature dependence and slope of thermal expansion align with those from measurements. Based on diffraction scans at select temperatures, ε phase remained stable in air up to at least 770 K. Likewise, dilatometry showed smooth thermal expansion up to the thermal decomposition temperature around 950 K. The precise decomposition temperature was not determined via diffraction due to sparse scanning. The complete elastic property measurements were gathered for ε-phase Ziracloy-4 hydride for the first time. Young's modulus was lower compared to the metal and δ hydride phases. High-temperature elasticity measurements were limited to <350 K due to acoustic dissipation effects.

KW - Crystal structure

KW - Elasticity

KW - Metal hydrides

KW - Neutron diffraction

KW - Thermal expansion

KW - Ultrasonics

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