SBIR-STTR Award

This Small Business Innovation Research (SBIR) Phase I project addresses challenges in producing an industrially-feasible alternative to rare-earth-based magnets. Rare earths comprise over 65% of all magnets in use today, which are sourced almost exclusively from China, and their production poses serious environmental concerns. While small samples of exotic materials can be produced in labs, this project aims to demonstrate the feasibility of producing a viable material at industrial volumes. The project addresses this challenge from two fronts: by evaluating a manufacturing scheme that is new to this class of material (magnets), and by producing a new type of material. The process innovation is the establishment of supercritical conditions in a continuous flow technology using a technology called ?microreactors?. This enhancement enables the manufacturing of difficult-to-stabilize nanoparticles at industrial scales by eliminating problems related to alternative formulations and facilitates the refinement of the final product. The second innovation is the discovery of a new ferromagnetic material based upon nanoscale cobalt carbide particles. The combination of the process with the product results in a material with superior cost performance compared to that of rare earth magnets in a wide range of applications.

The broader impact/commercial potential of this project is the future mitigation of supply and pricing risk in the magnet supply chain due to an imminent shortage of rare earths. Further, this innovation is expected to prove disruptive to existing global markets, will help reinvigorate the US manufacturing industry by creating skilled jobs on US soil, and will help offset the environmental impact associated with the mining and refinement of rare earths. The magnet described herein will be a price-competitive alternative to all commercial magnet types, including rare earth magnets, in a number of applications. In the short term, it will help absorb unmet demand arising from the rare earth shortage. In the long term, it should penetrate a wide range of markets. The total global market for this product is on the order of several hundred million dollars. Finally, by reducing the reliance on rare earth materials, this magnet alleviates national security risks associated with shortages in Chinese sources for rare earths. The research will extend the use of an existing technology-microreactors-to make completely new materials, thus building a basis for new production technologies and making feasible new materials categories.

The broader impact/commercial potential of this Small Business Innovation Research (SBIR) Phase II project is in launching a scalable, environmentally-safe, chemical manufacturing process capable of producing high performance, cost-competitive, and domestically-sourced magnetic materials suitable for a large range of industrial and consumer applications. This will drive jobs growth in the US, reduce supply chain risk, improve national security by reducing reliance on foreign sole sources for critical materials, and enable greater energy efficiency nationwide. Nanofoundry's carbide-based nanostructured magnet material represents the first major innovation in permanent magnetic materials since the early 1980's. In combination with an innovative manufacturing method, Nanofoundry expects to produce a large range of high value nanoparticle materials at low cost at industrial volumes. The permanent magnet market is $14 billion and is growing at nearly 9% annually. Nanofoundry projects that its first generation product, Cobalt Carbide nanoparticles, could capture $600 million of that market in 2018 dollars and that its second generation product (for which this project is foundational), could have an 80% to 90% cost advantage over current products, with the potential to capture over 30% of the global market. This project will break through historical barriers in two areas: launching a new product technology to the magnet market-the first transformational innovation in three decades-and developing a commercially-viable manufacturing capability to produce high-quality magnetic nanoparticle material at industrial scales. The specific focus of this project is to develop a scalable chemical production process to manufacture magnetic Cobalt Carbide nanoparticle material, and to prototype the use of the material in an end-use application. Several key innovations of this program include (1) the optimization of a class of cobalt carbide nanoparticles for use as a permanent magnet material, (2) the application of continuous flow microreactor wet chemical process technology to the manufacturing of high quality nanoparticle carbides at large scale, and (3) the use of supercritical solvents for efficiency and environmentally-friendly processing.