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A research collaboration has found an efficient way to expand the collective behavior of swarming microrobots: Mixing different sizes of the micron-scale ‘bots enables them to self-organize into diverse patterns that can be manipulated when a magnetic field is applied.
Researchers in the School of Electrical and Computer Engineering are incorporating elements of physics, circuit design, photonics, systems architecture, information theory and other fields to make quantum devices both practical and scalable.
Researchers have derived a formula that predicts the effects of environmental noise on quantum information – an advancement crucial for designing and building quantum computers capable of working in an imperfect world.
A simple model that simultaneously simulates swarming behaviors and synchronized timing takes a step toward engineering microrobots and furthering our understanding of such phenomena in biology.
Cornell students heading to Vanderbilt University for the Clinton Global Initiative University 2023 Annual Meeting will work on solutions for challenges facing their campuses, communities and the world.
Assistant professor Amal El-Ghazaly received an NSF CAREER Award for research that could ultimately make next-generation wireless systems more accessible worldwide.
Researchers designed a new system of fluid-driven actuators that enable soft robots to achieve more complex motions, leveraging the very thing – viscosity – that had previously stymied their movement.
Cornell is leading a new $34 million research center that will accelerate the creation of energy-efficient semiconductor materials and technologies, and develop revolutionary new approaches for microelectronics systems.
The robot’s layered filtration system will gather tiny bits of plastic the size of a sesame seed and smaller, which contaminate ecosystems and damage human and animal health.
Data science, molecular mechanisms, unconventional computing for optimization and machine learning, wave interaction with engineered materials, electrocatalysis, and compound semiconductor devices are among some of the research themes that helped six faculty members earn Cornell Engineering Research Excellence Awards.
