Computer model enables design of complex DNA shapes
Engineers computer-design the most complicated 3-D structures ever made from DNA.
3 Questions: Lee Gehrke on a new paper diagnostic for Ebola
Simple device now in development could speed diagnosis and improve disease tracking.
Alloying tougher tungsten
MIT graduate student Zack Cordero deforms and compacts chromium-tungsten powders to create stronger metals with nanoscale microstructure.
Catalyzing greener products
Yuriy Román knew that to change the future of catalysis he’d have to cross the boundary between chemical engineering and materials science.
New 2-D quantum materials for nanoelectronics
MIT team provides theoretical roadmap to making 2-D electronics with novel properties.
Two sensors in one
Nanoparticles that enable both MRI and fluorescent imaging could monitor cancer, other diseases.
Atomic timekeeping, on the go
New approach may enable more stable and accurate portable atomic clocks.
Dresselhaus and Solow win Presidential Medal of Freedom
Two Institute Professors are among 19 new recipients of the nation’s highest civilian honor.
Nanoscale work yields big results
Silvija Gradečak’s nanoscale work creates big-scale results that could transform energy production, storage, and lighting.
New way to make batteries safer
Coating prevents electrical current from damaging the digestive tract after battery ingestion.
Outside-the-box thinker
Senior Nathan Spielberg uses 3-D printing to build everything from nanoscale chips to houses.
Faculty highlight: Christopher Schuh
Metallurgist pushes grain boundaries: Nanostructured metal alloys deliver tougher materials, lower costs, and safer outcomes.
Microscopic “walkers” find their way across cell surfaces
Technology could provide a way to deliver probes or drugs to cell structures without outside guidance.