Toward more efficient computing, with magnetic waves
Circuit design offers a path to “spintronic” devices that use little electricity and generate practically no heat.
Circuit design offers a path to “spintronic” devices that use little electricity and generate practically no heat.
Series featured five experts who played seminal roles in understanding the nanoscale.
Ultrathin coating could protect 2D materials from corrosion, enabling their use in optics and electronics.
Five software and hardware projects will launch the MIT.nano Immersion Lab Gaming Program.
Researchers integrate diamond-based sensing components onto a chip to enable low-cost, high-performance quantum hardware.
Students on UROP teams agree that teamwork speeds up the research.
New detection tool could be used to make quantum computers robust against unwanted environmental disturbances.
Observation of the predicted non-Abelian Aharonov-Bohm Effect may offer step toward fault-tolerant quantum computers.
New technique could help doctors determine whether patients are at risk from elevated pressure.
When time matters in hospitals, automated system can detect an early biomarker for the potentially life-threatening condition.
New MIT system of contracting fibers could be a boon for biomedical devices and robotics.
Method for collecting two electrons from each photon could break through theoretical solar-cell efficiency limit.
Annual MITEI awards support research on methane conversion, efficient energy provision, plastics recycling, and more.
Simulations suggest photonic chip could run optical neural networks 10 million times more efficiently than its electrical counterparts.
New dual-cavity design emits more single photons that can carry quantum information at room temperature.