Ceramic Matrix Composites for High-Temperature Structural Applications
Materials & Manufacturing, RX/Composites
Fundamental scientific issues remain to be addressed to enable the development of a full range of high-performance ceramics and ceramic-matrix composites for Air Force air and space applications. These issues encompass basic design, new constituents, compatible chemistries, and enabling processes for oxide and nonoxide ceramic matrix composites. Current research focuses on investigating higher temperature nonoxide fiber and matrix constituents for enhanced durability and developing related fabrication processes, investigating the stability of consitituents in aggresive oxidizing environments, and understanding those key environmental effects on constituent-level behavior that affect life in relevant service environments. Modeling of ceramic matrix composite fabrication processes and degradation mechanisms is of particular interest. Intended service environments for these composites include turbine engines and scramjet engines, as well as hot structures and thermal protection systems for hypersonic vehicles.
Experience Supplement
Postdoctoral and Senior awardees will receive an appropriately higher stipend based on the number of years of experience past their PhD.
Awardees who reside more than 50 miles from their host laboratory and remain on tenure for at least six months are eligible for paid relocation to within the vicinity of their host laboratory.
A group health insurance program is available to awardees and their qualifying dependents in the United States.