The U.S. Department of Energy is accepting applications for a total of up to $74 million to support the research and development of clean, reliable fuel cells for stationary and transportation applications. The solicitations include up to $65 million over three years to fund continued research and development (R&D) on fuel cell technology components, such as catalysts and membrane electrode assemblies, with the goal of reducing costs, improving durability and increasing the efficiency of fuel cell systems. The funding also includes up to $9 million to conduct independent cost analyses that will assess the progress of the technology under current research initiatives and help guide future fuel cell and hydrogen storage R&D efforts. These awards will help support U.S. leadership in the emerging global fuel cell market, while limiting greenhouse gas emissions and reducing the country’s reliance on fossil fuels.
The Department will be funding research and development initiatives related to fuel cell system balance-of-plant components, fuel processors, and fuel cell stack components such as catalysts and membranes, as well as innovative concepts for both low and high temperature systems to help meet commercial viability targets in terms of cost and performance. Applicants will likely include teams of university, industry and national laboratory participants.
The cost analysis funding opportunity will help to determine the economic viability and technical progress of fuel cell and hydrogen technologies for stationary, transportation, and emerging market applications, including light duty vehicles, forklifts, buses and stationary power plants, as well as hydrogen storage systems. Under the program, the grantees will be expected to conduct life cycle cost analyses for different manufacturing volumes to help gauge the near-term, low-volume market viability for these technologies, along with their long-term potential.
Fuel cells use the chemical energy of hydrogen or other fuels to cleanly and efficiently produce electricity or heat with minimal byproducts, primarily water. They can produce power in large stationary systems such as buildings or for vehicles such as commercial forklifts, buses and automobiles.