Cornell researchers developed a multimodal platform to image microbe-semiconductor biohybrids with single-cell resolution, to better understand how they can be optimized for more efficient energy conversion.
Cornell researchers have identified a new way to measure DNA torsional stiffness – how much resistance the helix offers when twisted – information that can potentially shed light on how cells work.
A university committee has released recommendations for how faculty can take generative artificial intelligence into account when considering learning objectives for their students.
Identical twins Ashley and Verena Padres ’26 fell in love with the idea of space exploration and working together at an early age – now they employ and enjoy that spirit of curiosity and collaboration at Cornell.
Indigenous students in STEM are creating community and working to increase representation and visibility – all while bringing valuable cultural insights and a community-focus to their academic work.
Cornell researchers designed a micro-sized artificial cilial system that could eventually enable low-cost, portable diagnostic devices for testing blood samples, manipulating cells or assisting in microfabrication processes.
Cornell researchers have for the first time characterized a key property of the superconducting state of a class of atomically thin materials that are too difficult to measure due to their minuscule size.
As the world seeks to avoid climate extremes, employing state-of-the art agricultural technology could result in more than 13 billion tons of net negative greenhouse gas emissions annually.
The $500,000 pre-purchase agreement is intended to support technology developed in the lab of Greeshma Gadikota and licensed through Cornell University’s Center for Technology Licensing.