The aggressive approach, which supplements other campus efforts to slow the virus’s spread, expands testing to those who may not meet the definition of a close contact.
Cornell researchers have discovered a rare “pseudogap” phenomenon that helps explain how the superconducting transition temperature can be greatly boosted in a single monolayer of iron selenide, and how it might be applied to other superconducting materials.
Cornell and the City College of New York research shows that by creating steep tolls for cars to enter Manhattan, traffic congestion and greenhouse gas emissions could be reduced.
Cornell scientists from the College of Engineering have identified nitrides as new contenders when it comes to quantum materials for computing and low-temperature electronics.
The National Science Foundation has renewed its funding for the Cornell NanoScale Science and Technology Facility with a five-year, $7.5 million grant.
A Cornell-led research team’s improved cell therapy device effectively secreted insulin and controlled blood sugar in diabetic mice for up to six months – showing promise for the possibility of an effective, complication-free treatment for Type 1 diabetes, a chronic disease with no known cure.
Cornell researchers have helped develop a nasal formulation that blocks the spread of COVID-19 among ferrets – and are hopeful the formulation could have the same effect on humans, and potentially generate therapeutic treatments as well.
Cornell researchers discovered a way to bind and stack nanoscale clusters of copper molecules that can self-assemble and mimic complex biosystem structures at different length scales.
With Cornellian help, NASA's Mars 2020 mission’s Perseverance craft zips through space at 48,000 mph to our neighboring red planet. It is scheduled to land Feb. 18.
An interdisciplinary team’s work will help researchers who are custom-tailoring the properties of metal oxides in technologies such as lithium ion batteries, fuel cells and electrocatalysis.