Benchtop-Scale High Temperature Molten Salt Electrochemical Reactors: Experimental Setup and Considerations: Article No. 1

Haley Hoover; Ivy Wu; Oluwatamilore Olushina; Robert Bell; Kerry Rippy

doi:10.70163/2997-8947.1006

Benchtop-Scale High Temperature Molten Salt Electrochemical Reactors: Experimental Setup and Considerations: Article No. 1

Haley Hoover, Ivy Wu, Oluwatamilore Olushina, Robert Bell, Kerry Rippy

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

Abstract

Molten salt electrochemical reduction (MSER) is the dominant production method for aluminum and titanium, and emerging technologies for producing other commodity metals with these highly electrified techniques have demonstrated promising results. However, the scale up of MSER of materials such as iron and silicon are limited by the challenging issues of materials compatibility and impurity control. This work describes an experimental MSER setup using both chloride and carbonate salts. This setup is designed for operations outside of a glovebox, which is practical from an industrial perspective, but creates unique challenges. This work serves as a practical guide to discuss some key operational difficulties such as temperature control, air and humidity, material compatibility, developing strong electrical measurements and techniques, and safety.

Original language	American English
Number of pages	16
Journal	Reviews, Analyses, and Instructional Studies in Electrochemistry (RAISE)
Volume	2
DOIs	https://doi.org/10.70163/2997-8947.1006
State	Published - 2025

NREL Publication Number

NREL/JA-5500-92357

Keywords

electrochemistry
molten salts

Access to Document

10.70163/2997-8947.1006

https://www.nrel.gov/docs/fy25osti/92357.pdf

Cite this

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title = "Benchtop-Scale High Temperature Molten Salt Electrochemical Reactors: Experimental Setup and Considerations: Article No. 1",

abstract = "Molten salt electrochemical reduction (MSER) is the dominant production method for aluminum and titanium, and emerging technologies for producing other commodity metals with these highly electrified techniques have demonstrated promising results. However, the scale up of MSER of materials such as iron and silicon are limited by the challenging issues of materials compatibility and impurity control. This work describes an experimental MSER setup using both chloride and carbonate salts. This setup is designed for operations outside of a glovebox, which is practical from an industrial perspective, but creates unique challenges. This work serves as a practical guide to discuss some key operational difficulties such as temperature control, air and humidity, material compatibility, developing strong electrical measurements and techniques, and safety.",

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AU - Wu, Ivy

AU - Olushina, Oluwatamilore

AU - Bell, Robert

AU - Rippy, Kerry

PY - 2025

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AB - Molten salt electrochemical reduction (MSER) is the dominant production method for aluminum and titanium, and emerging technologies for producing other commodity metals with these highly electrified techniques have demonstrated promising results. However, the scale up of MSER of materials such as iron and silicon are limited by the challenging issues of materials compatibility and impurity control. This work describes an experimental MSER setup using both chloride and carbonate salts. This setup is designed for operations outside of a glovebox, which is practical from an industrial perspective, but creates unique challenges. This work serves as a practical guide to discuss some key operational difficulties such as temperature control, air and humidity, material compatibility, developing strong electrical measurements and techniques, and safety.

KW - electrochemistry

KW - molten salts

U2 - 10.70163/2997-8947.1006

DO - 10.70163/2997-8947.1006

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JO - Reviews, Analyses, and Instructional Studies in Electrochemistry (RAISE)

JF - Reviews, Analyses, and Instructional Studies in Electrochemistry (RAISE)

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