Metals and Metallic Nanostructures (MMN)
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Important Information for Proposers
ATTENTION: Proposers using the Collaborators and Other Affiliations template for more than 10 senior project personnel will encounter proposal print preview issues. Please see the Collaborators and Other Affiliations Information website for updated guidance.
A revised version of the NSF Proposal & Award Policies & Procedures Guide (PAPPG) (NSF 17-1), is effective for proposals submitted, or due, on or after January 30, 2017. Please be advised that, depending on the specified due date, the guidelines contained in NSF 17-1 may apply to proposals submitted in response to this funding opportunity.
The Metals and Metallic Nanostructures (MMN) Program supports fundamental research and education on the relationships between processing, structure and properties of metals and their alloys. The program focuses on experimental research while strongly encouraging the synergistic use of theory and computational materials science. Structure spanning atomic, nanometer, micrometer and larger length scales controls properties and connects these with processing. The program emphasizes the role of structure across all these length scales, including structural imperfections such as vacancies, solutes, dislocations, boundaries and interfaces. Research should advance fundamental materials science that will enable the design and synthesis of metallic materials to optimize superior behaviors and enable the prediction of properties and performance. The program aims to advance the materials science of metals and alloys through transformative research on a diverse array of topics, including, but not limited to, phase transformations; equilibrium, non-equilibrium and far-from equilibrium structures; thermodynamics; kinetics; diffusion; interfaces; oxidation; performance in extreme environments; recyclability; magnetic behavior; thermal transport; plastic flow; and similar phenomena. Yield strength, flow stress, creep, fatigue and fracture are structural-materials examples. Magnetic energy density, shape-memory strain and thermoelectric efficiency are examples for functional materials. Broader impacts are expected in education and other areas, such as workforce development, sustainability, environmental impact or critical infrastructure needs. High-quality proposals that integrate research, education, and other broader impacts are invited.