Solving a machine-learning mystery
A new study shows how large language models like GPT-3 can learn a new task from just a few examples, without the need for any new training data.
A new study shows how large language models like GPT-3 can learn a new task from just a few examples, without the need for any new training data.
A new tool brings the benefits of AI programming to a much broader class of problems.
The system’s simple repeating elements can assemble into swimming forms ranging from eel-like to wing-shaped.
MIT engineers developed organic polymers that can efficiently convert signals from biological tissue into the electronic signals used in transistors.
With a grant from the Office of Naval Research, MIT researchers aim to design novel high-performance steels, with potential applications including printed aircraft components and ship hulls.
Study reveals key cell structures and gene expression changes near amyloid plaques and tau tangles in mouse brain tissue.
A new study reveals that lymph nodes near the lungs create an environment that weakens T-cell responses to tumors.
First detailed mapping and modeling of thalamus inputs onto visual cortex neurons show brain leverages “wisdom of the crowd” to process sensory information.
Professor Heather Hendershot’s new book about that year’s Democratic National Convention explores how anger at the media became part of our culture wars.
Stacking light-emitting diodes instead of placing them side by side could enable fully immersive virtual reality displays and higher-resolution digital screens.
The findings could provide a new way to control chemical reactions.
Researchers urge industry and the research community to explore electrification pathways to reduce chemical industry emissions.
A new computational framework could help researchers design granular hydrogels to repair or replace diseased tissues.
With this microfluidic device, researchers modeled how sickled blood cells clog the spleen’s filters, leading to a potentially life-threatening condition.
A quick electric pulse completely flips the material’s electronic properties, opening a route to ultrafast, brain-inspired, superconducting electronics.