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Cornell engineers have created a deep-ultraviolet laser using semiconductor materials that show great promise for improving the use of ultraviolet light for sterilizing medical tools, purifying water and sensing hazardous gases.
Ten assistant professors representing four colleges have recently received National Science Foundation Faculty Early Career Development Awards to support their research objectives.
A crystal structure that combines a semiconductor and superconductor is a tantalizing prospect to create energy-efficient computers, or quantum computers, which leverage the unique quantum mechanical properties of superconductors. Superconductors carry current with little to no energy loss, while semiconductors offer the control and versatility that has made them an essential feature of transistor technology.
Forty-three high school juniors and seniors teamed up remotely from July 19-23 to build an interconnected system of hardware and software as part of Cornell Engineering’s annual CURIE Academy.
Cornell researchers are proposing a new way to modulate both the absorptive and the refractive qualities of metamaterials in real time, and their findings open intriguing new opportunities.
Honeybees are skilled architects who plan ahead and solve design challenges when constructing honeycombs, offering strategies that engineers may learn from when they use honeycomb structures in industry.
A new AI-based technology developed by Cornell researchers will help gain new insights into how our brains respond to external stimuli.
Cornell engineers and plant scientists have teamed up to develop a low-cost system that allows grape growers to predict their yields much earlier in the season and more accurately than costly traditional methods.
Cornell researchers are pioneering an innovative approach for the wireless charging of electric vehicles and other machines while they remain in motion.
Engineers received an $880,000 National Science Foundation grant to design a new class of radio devices capable of operating across a large portion of the wireless spectrum while adaptively suppressing interferences.
