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A new study by U.S. National Science Foundation-funded researchers on how members of the animal world sense and react to sounds provides insight into adaptations in communication that could be used in the development of adaptable hearing aids or limiting the impact of agricultural pests.

“By increasing our understanding of how animals perceive and respond to sounds — especially when those sounds are changing — this research could aid in developing hearing aids that automatically tune as a person walks from a movie theater to a crowded restaurant or other adaptive hearing and acoustics devices,” said Jodie Jawor, a program director in the NSF Directorate for Biological Sciences. “It also highlights how agricultural pests can move into an area and capitalize on a new host, harming society in the process — think about a parasite of honeybees that hurts their populations and our food supply.”

The study focused on the interactions between a species of fly (Ormia ochracea) and Pacific crickets, which are engaged in a sort of sound arms race. The fly can hear the mating chirps of the male cricket and uses the sounds to locate the male, in which the fly lays its eggs. The fly larvae feed on and develop inside of their cricket hosts, eventually killing them when they emerge. Some crickets in Hawaii have responded to this threat

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RSS feed source: National Science Foundation

A new study supported by the U.S. National Science Foundation shows, for the first time, how heat moves — or rather, doesn’t — between materials in a high-energy-density plasma state. The work is expected to provide a better understanding of inertial confinement fusion experiments, which aim to reliably achieve fusion ignition on Earth using lasers. How heat flows between a hot plasma and a material’s surface is also important in other technologies, including semiconductor etching and vehicles that fly at hypersonic speeds.

High-energy-density plasmas are produced only at extreme pressures and temperatures. The study shows that interfacial thermal resistance, a phenomenon known to impede heat transfer in less extreme conditions, also prevents heat flow between different materials in a dense, super-hot plasma state. The research is published in Nature Communications and was led by Thomas White, a physicist at the University of Nevada, Reno, and his former doctoral student, Cameron Allen. White is a recipient of an NSF Faculty Early Career Development grant.

“Understanding how energy flows across a boundary is a fundamental question, and this work provides us with new insights into how this happens in the exceptionally energy-dense environments that one finds inside of stars and planetary cores,” says Jeremiah Williams, a program director for the NSF Plasma Physics program.