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After losing his mother to breast cancer, Ryan Nowicki '16 crowdfunded for a novel cancer treatment that had once piqued the interest of his mother at Cornell.
A new metal organic chemical vapor deposition system will be used to engineer and study gallium oxide, an important material for the future of high-powered electronics.
Producing biomaterials that match the performance of cartilage and tendons has been an elusive goal for scientists, but a new material created at Cornell demonstrates a promising new approach to mimicking natural tissue.
A Cornell-led project has created synthetic nanoclusters that can mimic hierarchical self-assembly all the way from the nanometer to the centimeter scale, spanning seven orders of magnitude.
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.
The Ezra’s Bridge program aims to address challenges faced by populations underrepresented in chemical and materials sciences by providing students with a full-tuition scholarship, research opportunities and mentoring.
A new X-ray technique developed at Cornell offers an unprecedented look at the elaborate inner workings of batteries while they are in use – a breakthrough that is already yielding important findings for the development of next-generation energy storage.
A new artificial intelligence tool developed by Cornell researchers promises to help speed up searches for novel metastable materials with unique properties in fields such as renewable energy and microelectronics.
