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The Office of Naval Research's Polymer Matrix Composites (PMC) program has invested significantly in developing new structural fibers with better thermo-oxidative resistance, new non-toxic resins systems and sandwich cores with enhanced resistance to fire and its propagation, new additives to improve PMC inter-laminar properties, and new resin infusion models and processing tools for improving product quality and lowering manufacturing costs.

The Office of Naval Research's Propulsion Materials program involves, in part, the kinetics and thermodynamics of materials interactions and materials stability under marine operating environments and temperatures.

The Office of Naval Research's Structural Metals program emphasizes developing the fundamental understanding needed to discover, design, and produce high-performance structural metals.

The Navy faces the complex task of efficiently managing diverse material streams, either generated as operational byproducts or at the end of their service life. The Office of Naval Research's Materials Treatment and Recovery program ensures their appropriate treatment and, where economically feasible, resource recovery.

The Office of Naval Research's Artificial Intelligence/Machine Learning for Photonics, Power & Energy, Atmospherics, and Quantum Science program is focused on machine learning techniques that can be applied to photonics, power and energy, thermal management and controls, atmospherics, communication, and quantum science for improved naval capabilities.

The Navy ManTech program responds to naval needs for the production and repair of platforms, systems and equipment.

The Office of Naval Research's Electrochemical Materials program is focused on developing a fundamental understanding of charge (electron and ion) storage, transport and transfer mechanisms, and applying that knowledge to inform the development of materials, materials architectures and devices that address Navy and Marine Corps application power and energy needs.

The Office of Naval Research's Corrosion Science and Corrosion Control Technologies program has a primary focus to create a science-based understanding of corrosion through damage evolution mechanisms, develop corrosion-informed materials concepts, and evolve surface protection and modification sciences.

Extraordinarily rugged with a melting temperature of several thousand degrees Fahrenheit. That describes the results of research into new ceramic materials sponsored by the Office of Naval Research (ONR) and recently published in the Journal Nature. A research team, led by ONR’s Principal Investigator, Dr. Stefano Curtarolo, Duke University, developed a computational method for creating new types of ceramics using transition metals – carbonitrides or borides – through a process called Disordered Enthalpy-Entropy Descriptor (DEED). The applications are endless, said Dr. Eric Wuchina, a research materials engineer who was the program officer with ONR’s Sea Warfare and Weapons department when Curtarolo’s research team was awarded the Multidisciplinary University Research Initiative (MURI). According to Wuchina, the variety of new compositions could create potentially millions of new materials.

The Office of Naval Research's Materials for New Sensor Modalities program is interested in basic research aimed at drastic or fundamental alterations of a material’s response to stimuli.