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a researcher looks through a small window on a large metal multichambered molecular beam epitaxy tool.
advanced materials
A new approach to materials discovery aims to expedite the process of deploying new materials for specific mission needs.
A photo of unmanned surface vehicles on the Charles River.
autonomous systems
We developed new distributed coordination algorithms for deploying multiple autonomous systems from a single set of operator commands.
A graph with the words HAPI Human AI-performance against a blue background. Surrounding the words are images of technologies, including a wristband, a laptop, a sensored helmet, VR glasses, and gloves.
artificial intelligence
A new collaboration space is empowering researchers to drive innovations in human-AI teaming.
A group of five researchers pose in a field with two UAVs.
autonomous systems
We are building a toolbox of autonomous functions for unmanned aerial systems to improve UAS missions and alleviate burden on human operators in the field.
Autonomous High-Resolution Ocean Floor Mapping
undersea technology
The Laboratory is working to develop a novel seabed-mapping capability that can achieve high-resolution imaging and a fast coverage rate.
This is an image of adiamond seed crystal that glows orange.
quantum systems and science
Engineered diamonds show promising capability for use in quantum sensing of magnetic fields.
Rice cooker with attached infrared sensor.
energy
By connecting a PV microgrid powered by solar panels to homes, engineers could provide people who live in regions of power-insecurity with the energy to cook their meals. Unused power could be applied to phone-charging stations.
Close-up of a 3D printed array
advanced devices
A new concept for a low-cost vacuum pump may enable development of a portable mass spectrometer that achieves high-performance chemical detection.
Three step progression of material in self repair, from cracked, to processing, to fully repaired.
advanced materials
New materials that are chemically inspired by nature could be tailored at the molecular level to dissipate vibrations in microsystems. Materials that can survive repeated external stresses could enable a next generation of enhanced microsystems.

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