Conference Tools for 2020 TMS Annual Meeting & Exhibition

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Meeting	2020 TMS Annual Meeting & Exhibition
Symposium	Process Metallurgy and Electrochemistry of Molten Salts, Liquid Metal Batteries, and Extra-terrestrial Materials Processing: An EPD Symposium in Honor of Don Sadoway
Presentation Title	Molten Oxide Electrolysis for the Production of Ferroalloys and Steel
Author(s)	Guillaume Lambotte, Richard Bradshaw, Tadeu Carneiro
On-Site Speaker (Planned)	Guillaume Lambotte
Abstract Scope	Molten Oxide Electrolysis has been studied for decades at MIT by Professor Donald R. Sadoway. With support from NASA, the American Iron and Steel Institute, and the Deshpande Center at MIT, Prof. Sadoway’s laboratory demonstrated, at the laboratory-scale, that molten oxide electrolysis (MOE) could produce oxygen on the Moon as well as numerous metals here on Earth. In 2013, Antoine Allanore, Lan Yin and Donald R. Sadoway published results that showed that iron oxide can be reduced by MOE using an inert anode, therefore creating the opportunity for emission-free steel production. Boston Metal was founded by Prof. Sadoway, Prof. Allanore and Dr. Yurko to scale up the technology by addressing the scientific and technical challenges at a scale a thousand times larger than the laboratory experiments at MIT. Here we present some of the results obtained at the pilot-scale for the production of ferroalloys and steel.
Proceedings Inclusion?	Planned: Supplemental Proceedings volume

OTHER PAPERS PLANNED FOR THIS SYMPOSIUM

Application of Electronically Mediated Metallothermic Reductions in Molten Salts to Nuclear Materials

Are the Metallic Iron Inclusions Exist on the Surface of the Moon?

Better Living through Electrochemistry: A Career of Scientific Solutions and Pragmatism

Development of a New Electrodeposition Process based on Liquid Metal Electrochemical Technologies in Molten Salt Electrolytes

Electrochemical Processing under Extreme Conditions

Electrodeposition of Titanium from Alkali Fluoride-Chloride Molten Salts

Extraction of Magnesium from Aluminum Scrap Melts by Molten Salt Electrorefining

Fluid Mechanics of Liquid Metal Batteries: Overview and Outlook

Getting the Most from Models in High-Temperature Materials Processing

History of Inventions and Innovations for Aluminum Production

Hybrid Processes in Refining of Silicon

Innovative Ways to Chemically Process Rare-earth Waste Materials

Insights into the Oxidation Behavior of Cr1−xFex Anodes for Molten Oxide Electrolysis

Know Your Audience: Four Decades of Educational Innovation

Liquid Metal Batteries: From Concept to Commercialization

Lithium Metal Battery for Future Energy Storage

Molten Oxide Electrolysis for the Production of Ferroalloys and Steel

Open-circuit Explosions and Basement Thermite Fires Threaten Aluminum Potlines

Recovery of Metal Values from Wastes

Study of Electrode Performance Improvement with Infiltration of Electronic and Mixed-conducting Nanoparticles Employing Electrochemical Impedance Spectroscopy and I-V Measurements

Study on Electronically Mediated Reaction (EMR), and What I Learned from Professor Sadoway

The Application of the FFG Molten Salt Cycle on the Separation of the Refractory Metals

Thermodynamic and Kinetic Modelling of Molten Oxide Electrolysis Cells

Thermodynamics of Electrode Reactions for Energy Storage, Separation, and Corrosion

Titanium Extraction from Industrial Raw Material to Metal through Carbothermic Reduction and Molten Salts Electrolysis

Trends and Challenges for Electrowinning of Aluminium and Magnesium from Molten Salt Electrolytes

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