Quantum repeaters use defects in diamond to interconnect quantum systems
This technology for storing and transmitting quantum information over lossy links could provide the foundation for scalable quantum networking.
This technology for storing and transmitting quantum information over lossy links could provide the foundation for scalable quantum networking.
Staff share nano experience — and ice cream — with their families.
In a first, researchers have observed how lithium ions flow through a battery interface, which could help engineers optimize the material’s design.
Lincoln Laboratory hosts students enrolled in the Massachusetts Microelectronics Internship Program, aimed at training a new generation of microelectronics leaders.
The new approach could lead to intranasal vaccines for Covid-19 and other respiratory diseases.
Microbial or fungal biofilms on spacecraft can clog hoses and filters, or make astronauts sick. Space Station tests show that a surface treatment can help.
The ultrasmall “switch” could be easily scaled.
MIT engineers developed a new way to create these arrays, by scaffolding quantum rods onto patterned DNA.
By fine-tuning the spin density in some materials, researchers may be able to develop new quantum sensors or quantum simulations.
Researchers discover how to control the anomalous Hall effect and Berry curvature to create flexible quantum magnets for use in computers, robotics, and sensors.
The device detects the same molecules that cell receptors do, and may enable routine early screening for cancers and other diseases.
A new technique produces perovskite nanocrystals right where they’re needed, so the exceedingly delicate materials can be integrated into nanoscale devices.
The foundry gives the wider research community access to Lincoln Laboratory’s expertise in fabricating quantum circuits.
The disorganized arrangement of the proteins in light-harvesting complexes is the key to their extreme efficiency.