TY - JOUR
T1 - Sustainable and Energy-Efficient Production of Rare-Earth Metals via Chloride-Based Molten Salt Electrolysis
AU - Holcombe, Benjamin
AU - Sinclair, Nicholas
AU - Wasalathanthri, Ruwani
AU - Mainali, Badri
AU - Guarr, Evan
AU - Baker, Alexander A.
AU - Usman, Sunday Oluwadamilola
AU - Kim, Eunjeong
AU - Sen-Britain, Shohini
AU - Jin, Hongyue
AU - McCall, Scott K.
AU - Akolkar, Rohan
N1 - Publisher Copyright:
© 2024 American Chemical Society.
PY - 2024/3/11
Y1 - 2024/3/11
N2 - Neodymium metal is a critical component of rare earth magnets, essential for electric vehicles and the green energy transition, but its production has severe environmental impacts across its mining, separation, purification, and metal electrowinning steps. Specifically, conventional neodymium electrowinning in oxyfluoride molten salts using a consumable graphite anode generates greenhouse gases, e.g., carbon dioxide and perfluorocarbon (PFC). Here, we propose an alternative chloride-based molten salt electrolysis process utilizing a novel dimensionally stable anode (DSA). Our process lowers the specific electrical energy consumption compared to the state of the art, while producing reusable chlorine gas and eliminating direct CO2 and PFC emissions. Chloride-based molten salt electrolysis of NdCl3 (1.65 M) added to a LiCl-KCl eutectic (45:55 wt %), while using a RuO2-coated DSA enables high Coulombic efficiency (>80%), low specific energy consumption (2.3 kWh/kg-Nd), and excellent electrowon Nd product purity (>97 wt %). Life cycle analysis, excluding the common input feedstock (Nd2O3), shows that the global warming potential for the proposed chloride-based electrolysis approach is 5 kg CO2 equivalent, compared to 9-16 kg CO2 equivalent for the conventional process, representing a 44-69% reduction in CO2 emissions.
AB - Neodymium metal is a critical component of rare earth magnets, essential for electric vehicles and the green energy transition, but its production has severe environmental impacts across its mining, separation, purification, and metal electrowinning steps. Specifically, conventional neodymium electrowinning in oxyfluoride molten salts using a consumable graphite anode generates greenhouse gases, e.g., carbon dioxide and perfluorocarbon (PFC). Here, we propose an alternative chloride-based molten salt electrolysis process utilizing a novel dimensionally stable anode (DSA). Our process lowers the specific electrical energy consumption compared to the state of the art, while producing reusable chlorine gas and eliminating direct CO2 and PFC emissions. Chloride-based molten salt electrolysis of NdCl3 (1.65 M) added to a LiCl-KCl eutectic (45:55 wt %), while using a RuO2-coated DSA enables high Coulombic efficiency (>80%), low specific energy consumption (2.3 kWh/kg-Nd), and excellent electrowon Nd product purity (>97 wt %). Life cycle analysis, excluding the common input feedstock (Nd2O3), shows that the global warming potential for the proposed chloride-based electrolysis approach is 5 kg CO2 equivalent, compared to 9-16 kg CO2 equivalent for the conventional process, representing a 44-69% reduction in CO2 emissions.
KW - critical metals
KW - dimensionally stable anode
KW - electrowinning
KW - life cycle assessment
KW - molten salt electrolysis
KW - rare-earth metals
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U2 - 10.1021/acssuschemeng.3c07720
DO - 10.1021/acssuschemeng.3c07720
M3 - Article
AN - SCOPUS:85186409270
SN - 2168-0485
VL - 12
SP - 4186
EP - 4193
JO - ACS Sustainable Chemistry and Engineering
JF - ACS Sustainable Chemistry and Engineering
IS - 10
ER -