Irradiation, Heat, and Corrosion Resistant Hexagonal Boron Nitride-Cement Coating For Mitigating Aging and Irradiation Effects in Nuclear Power Plants
This topic would develop extremely durable concretes and cementitious materials to tackle technology challenges in the development of widely applicable concrete and cement. Cement is the second most used substance in the world (next to water), largely due to its low cost, abundance, and reliability in a wide variety of environments. Cement has been a LITERAL building block of society dating back to the ancient Egyptians, Greeks, and Romans, but current production and utilization methods pose significant energy and emissions challenges. These threaten cement’s growth as domestic infrastructure degrades with age. Cement is important to U.S. energy production, as well as to infrastructure industry. The International Energy Agency estimated that in 2016 the cement and concrete sector consumed 10.5 exa-joules of energy and generated 2.2 gigatons of CO2 emissions globally. ARPA-E is seeking to develop novel materials for infrastructure with improved performance and lifetime and lower energy and emissions impacts. These projects present opportunities to develop material and process improvements that could improve the durability of cement, while maintaining or lowering production and deployment-related emissions. They could also ensure new types of cement are cost-competitive with existing traditional materials.
Project Innovation + Advantages:
Develop next generation cementitious coating materials to extend the lifetime of key infrastructures subject to extreme conditions such as nuclear power plants. Strategically couple emerging 2D materials technology with lamellar structure of low-CO2 cement to impart greater synergy.