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Cornell wind energy scientists, Sara C. Pryor and Rebecca Barthelmie, have released a new global wind atlas – a digital compendium filled with documented extreme wind speeds for all parts of the world – to help engineers select the turbines in any given region and accelerate the development of sustainable energy.
Organic Robotics Corporation, a Cornell startup founded by Associate Professor Rob Shepherd and his former Ph.D. student, Ilayda Samilgil '19, will compete in the sixth annual NFL 1st & Future competition, to be televised Feb. 2 at 8 p.m. EST on the NFL Network.
A team led by Assistant Prof Mahdi Esmaily developed a transparent helmet that prevents 99.6% of virus-containing droplets exhaled by patients from reaching the environment during open-face procedures.
K. Bingham Cady, professor emeritus of nuclear engineering in the Sibley School, died Dec 10. Cady helped improve the safety of nuclear fission reactors by developing computer modeling software that could simulate how reactors respond to operational fluctuations and accidents.
The Cornell Chronicle highlighted Associate Professor Rob Shepherd's research in their 2020 In Review article! Shepherd and his team developed a soft robot muscle that sweats to regulate its temperature.
Alexander Li ’20, an Energy and the Environment Research Lab member, was elected to join the sixth cohort of Schwarzman Scholars, a program that nurtures future global leaders.
A Cornell project funded by two separate three-year grants will develop worm-like, soil-swimming robots to sense and record soil properties, water, the soil microbiome and how roots grow.
A new fiber-optic sensor results in a stretchable “skin” that could give soft robotic systems the ability to feel the same sensations that mammals depend on to navigate the world. The sensor was developed by Associate Professor Rob Shepherd and his team.
A collaboration led by Assistant Professor Atieh Moridi has developed a 3D printing technique that creates cellular metallic materials by smashing together powder particles at supersonic speed that results in mechanically robust, porous structures that are 40% stronger than similar materials made with conventional manufacturing processes.
Douglas MacMartin will lead a team from the Cornell Climate Engineering group to model the effects of introducing reflective aerosols into the stratosphere, which could reduce Earth's temperature and limit the impact of climate change.
