Operando Neutron Imaging of Reaction Extent and Particle Swelling Informs Limiting Factors for Salt Hydrate Thermochemical Energy Storage

Bryan Kinzer; Jean Christophe Bilheux; Erik Stringfellow; Arijit Jatkar; Matthew McMullen; Hegang Zhi; Jing Tang; Yuxuan Zhang; Rohini Bala Chandran

doi:10.1021/acsmaterialslett.5c00986

Operando Neutron Imaging of Reaction Extent and Particle Swelling Informs Limiting Factors for Salt Hydrate Thermochemical Energy Storage

Bryan Kinzer
, Jean Christophe Bilheux
, Erik Stringfellow
, Arijit Jatkar
, Matthew McMullen
, Hegang Zhi
, Jing Tang
, Yuxuan Zhang
, Rohini Bala Chandran

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

Abstract

Salt hydrates are a promising thermochemical energy storage medium that stores heat through the reversible uptake (hydration) and release (dehydration) of water vapor. Our study deploys operando neutron imaging to investigate salt hydrate performance with high spatial resolution (42 μm pixels). For flow over a packed bed with diffusion-driven transport, measurements reveal the formation of a solid diffusion layer due to particle swelling for the pure SrBr₂salt. In contrast, the SrBr₂–vermiculite composite exhibits significantly less swelling and more than a 2-fold increase in the apparent water vapor diffusivity. For axial flow through a packed bed, neutron imaging confirms theoretically predicted transitions from a moving reaction front to a homogeneous profile with an increase in humid air flow rate. Our study establishes neutron imaging as a powerful technique to advance fundamental understanding of thermochemical systems and help guide composite material design.

Original language	English
Pages (from-to)	3936-3942
Number of pages	7
Journal	ACS Materials Letters
Volume	7
DOIs	https://doi.org/10.1021/acsmaterialslett.5c00986
State	Published - 2025

Funding

The authors acknowledge partial funding support from the University of Michigan Graham Sustainability Institute’s Carbon Neutrality Acceleration Program. R.B.C. and J.T. acknowledge startup funding from the College of Engineering and the Department of Mechanical Engineering at the University of Michigan. B.K. and R.B.C. were funded, in part, by the U.S. Department of Energy’s Energy Efficiency & Renewable Energy Office, under Award No. DE-EE0010732. This research used resources at the High Flux Isotope Reactor, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The beam time was allocated to MARS (CG-1D) on Proposal No. OPTS-30610.1. We are thankful to the machine shop staff at the Mechanical Engineering Department and technical support from the Michigan Center for Materials Characterization. We are also thankful for assistance from Declan Crowley at the University of Michigan with reactor parts prototyping and fabrication.

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10.1021/acsmaterialslett.5c00986

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title = "Operando Neutron Imaging of Reaction Extent and Particle Swelling Informs Limiting Factors for Salt Hydrate Thermochemical Energy Storage",

abstract = "Salt hydrates are a promising thermochemical energy storage medium that stores heat through the reversible uptake (hydration) and release (dehydration) of water vapor. Our study deploys operando neutron imaging to investigate salt hydrate performance with high spatial resolution (42 μm pixels). For flow over a packed bed with diffusion-driven transport, measurements reveal the formation of a solid diffusion layer due to particle swelling for the pure SrBr2salt. In contrast, the SrBr2–vermiculite composite exhibits significantly less swelling and more than a 2-fold increase in the apparent water vapor diffusivity. For axial flow through a packed bed, neutron imaging confirms theoretically predicted transitions from a moving reaction front to a homogeneous profile with an increase in humid air flow rate. Our study establishes neutron imaging as a powerful technique to advance fundamental understanding of thermochemical systems and help guide composite material design.",

author = "Bryan Kinzer and Bilheux, \{Jean Christophe\} and Erik Stringfellow and Arijit Jatkar and Matthew McMullen and Hegang Zhi and Jing Tang and Yuxuan Zhang and \{Bala Chandran\}, Rohini",

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year = "2025",

doi = "10.1021/acsmaterialslett.5c00986",

language = "English",

volume = "7",

pages = "3936--3942",

journal = "ACS Materials Letters",

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T1 - Operando Neutron Imaging of Reaction Extent and Particle Swelling Informs Limiting Factors for Salt Hydrate Thermochemical Energy Storage

AU - Kinzer, Bryan

AU - Bilheux, Jean Christophe

AU - Stringfellow, Erik

AU - Jatkar, Arijit

AU - McMullen, Matthew

AU - Zhi, Hegang

AU - Tang, Jing

AU - Zhang, Yuxuan

AU - Bala Chandran, Rohini

PY - 2025

Y1 - 2025

N2 - Salt hydrates are a promising thermochemical energy storage medium that stores heat through the reversible uptake (hydration) and release (dehydration) of water vapor. Our study deploys operando neutron imaging to investigate salt hydrate performance with high spatial resolution (42 μm pixels). For flow over a packed bed with diffusion-driven transport, measurements reveal the formation of a solid diffusion layer due to particle swelling for the pure SrBr2salt. In contrast, the SrBr2–vermiculite composite exhibits significantly less swelling and more than a 2-fold increase in the apparent water vapor diffusivity. For axial flow through a packed bed, neutron imaging confirms theoretically predicted transitions from a moving reaction front to a homogeneous profile with an increase in humid air flow rate. Our study establishes neutron imaging as a powerful technique to advance fundamental understanding of thermochemical systems and help guide composite material design.

AB - Salt hydrates are a promising thermochemical energy storage medium that stores heat through the reversible uptake (hydration) and release (dehydration) of water vapor. Our study deploys operando neutron imaging to investigate salt hydrate performance with high spatial resolution (42 μm pixels). For flow over a packed bed with diffusion-driven transport, measurements reveal the formation of a solid diffusion layer due to particle swelling for the pure SrBr2salt. In contrast, the SrBr2–vermiculite composite exhibits significantly less swelling and more than a 2-fold increase in the apparent water vapor diffusivity. For axial flow through a packed bed, neutron imaging confirms theoretically predicted transitions from a moving reaction front to a homogeneous profile with an increase in humid air flow rate. Our study establishes neutron imaging as a powerful technique to advance fundamental understanding of thermochemical systems and help guide composite material design.

UR - https://www.scopus.com/pages/publications/105021338390

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DO - 10.1021/acsmaterialslett.5c00986

M3 - Article

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SN - 2639-4979

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SP - 3936

EP - 3942

JO - ACS Materials Letters

JF - ACS Materials Letters

ER -

Operando Neutron Imaging of Reaction Extent and Particle Swelling Informs Limiting Factors for Salt Hydrate Thermochemical Energy Storage

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