SBIR-STTR Award

Innovative Process for Production of Neodymium Metal and Neodymium-Iron Master Alloy
Award last edited on: 9/24/2014

Sponsored Program
SBIR
Awarding Agency
DOE
Total Award Amount
$1,150,000
Award Phase
2
Solicitation Topic Code
02d
Principal Investigator
Robert Hyers

Company Information

Boston Metal (AKA: Boston Electrometallurgical Corporation)

6 Gill Street Unit A
Woburn, MA 01801
   (781) 281-7657
   info@bostonelectromet.com
   www.bostonelectromet.com
Location: Single
Congr. District: 05
County: Middlesex

Phase I

Contract Number: DE-SC0011943
Start Date: 6/9/2014    Completed: 3/8/2015
Phase I year
2014
Phase I Amount
$150,000
Neodymium is an essential element for the powerful permanent magnets used wind turbines, electric vehicles, and other applications. However, neodymium is classified by the Department of Energy as critical due to insufficient and insecure supply, including a virtual monopoly by a few companies in China. Even with the current expansion of rare earth mining in the US, Canada, and Australia, there is a gap in the supply chain where the ores and concentrates from these mines are converted into metals and alloys. Furthermore, incumbent technologies for producing metal from rare earth ores are inefficient, environmentally unfriendly, and unsustainable. The is molten oxide electrolysis (MOE), which will produce neodymium metal and alloys from concentrates efficiently and cleanly. This process involves fewer unit operations than incumbent processes, avoiding conversion of the feed into chlorides and fluorides. By completely eliminating fluorine and chlorine from the process, MOE avoids producing polyfluorinated carbons (PFCs), dioxins, furans, and hydrofluoric acid, and thus also avoids the necessity of cleaning up these emissions. In addition to the advantages in safety and environmental protection, eliminating these steps saves energy, capital, and operating expense. Commercial Applications and Other

Benefits:
Include safe, secure access to the materials needed for expanding the modern economy and increasing the deployment of renewable energy, at a lower cost in both economic and environmental terms. Diversity in the supply base may also help to defuse recent geopolitical tension over this critical material.

Phase II

Contract Number: DE-SC0011943
Start Date: 7/27/2015    Completed: 7/26/2017
Phase II year
2015
Phase II Amount
$1,000,000
Even with the current expansion of rare earth mining in the US, Canada, and Australia, there is a gas in the supply chain where the ores and concentrates from these mines are converted into metals and alloys. A novel technology for extraction of metals that is cleaner, greener, and cheaper than incumbent technologies has been developed. Neodymium is a essential element for the powerful permanent magnets used wind turbines, electric vehicles, and other applications. However, neodymium is classified by the Department of Energy as critical due to insufficient and insecure supply, including a virtual monopoly by a few companies in China. Furthermore, incumbent technologies for producing metal from rare earth ores are inefficient, environmentally unfriendly, and unsustainable. The proposed solution is molten oxide electrolysis (MOE), which will produce neodymium metal and alloys from concentrates efficiently and cleanly. MOE involves fewer unit operations than incumbent process. MOE avoids producing polyfluorinated carbons (PFCs), dioxins, furans, and hydrofluoric acid and this also avoids the necessity of cleaning up these emissions. In addition to the advantages in safety and environmental protection, eliminating these steps saves energy, capital, and operating expense. The Phase I project addressed several critical technical risks: design of the supporting electrolyte, containment of the product, and thermal balance in the reactor. A proprietary electrolyte that will serve as a good starting point for optimization has been identifies through the use of computational thermodynamics and thermodynamic databases. A concept for containment of the product while minimizing contamination has been developed. Models for the thermal optimization of the reactor have been extended and applied to the proposed electrolyte system. An experimental run in pilot-scale reactor conducted, using a surrogate system that captures many of the key chemical and physical characteristics of the electrolyte to be used to produce neodymium in Phase II. In Phase II, the focus is applying the results of the Phase I to the successful production of neodymium. A pilot-scale cell will be modified as determined in the Phase I and operate with the electrolyte identified in Phase I to produce neodymium. The energy consumption, current efficiency, and production rate of neodymium will be measured as they were in the Phase I experiments with a surrogate system. The Phase II study will result in neodymium produced by MOE, details of the chemical profile of that product, and its cost and energy consumption, all measured experimentally.