MIT engineers advance toward a fault-tolerant quantum computer
Researchers achieved a type of coupling between artificial atoms and photons that could enable readout and processing of quantum information in a few nanoseconds.
Researchers achieved a type of coupling between artificial atoms and photons that could enable readout and processing of quantum information in a few nanoseconds.
Clinical trial finds several outcomes improved for young children when an anesthesiologist observed their brain waves to guide dosing of sevoflurane during surgery.
Professor Thomas Peacock’s research aims to better understand the impact of deep-sea mining.
Upon infection, the C. elegans worm reshuffles the roles of brain cells and flips the functions of some of the chemicals it uses to regulate behavior.
Mingmar Sherpa, a researcher in the Martin Lab in the Department of Biology, has remained connected to his home in Nepal at every step of his career.
Researchers showed they can inexpensively produce silk microneedles to deliver vitamins or agrochemicals to plants.
Preventing 3D integrated circuits from overheating is key to enabling their widespread use.
The MESA method uses ecological theory to map cellular diversity and spatial patterns in tissues, offering new insights into disease progression.
The circuits could help researchers develop new treatments for fragile X syndrome and other diseases caused by mutations of a single gene.
Using diagrams to represent interactions in multipart systems can provide a faster way to design software improvements.
A new approach could enable intuitive robotic helpers for household, workplace, and warehouse settings.
Since an MIT team introduced expansion microscopy in 2015, the technique has powered the science behind kidney disease, plant seeds, the microbiome, Alzheimer’s, viruses, and more.
MIT engineers developed ultrathin electronic films that sense heat and other signals, and could reduce the bulk of conventional goggles and scopes.
Chemists could use this quick computational method to design more efficient reactions that yield useful compounds, from fuels to pharmaceuticals.
A new method could enable stretchable ceramics, glass, and metals, for tear-proof textiles or stretchy semiconductors.