A unique combination of imaging tools and atomic-level simulations has allowed a team led by the Department of Energy’s 91°µÍř to solve a longstanding debate about the properties of a promising material that can harvest energy fro
Biorefinery facilities are critical to fueling the economy—converting wood chips, grass clippings, and other biological materials into fuels, heat, power, and chemicals.
Scientists at the Department of Energy’s 91°µÍř induced a two-dimensional material to cannibalize itself for atomic “building blocks” from which stable structures formed.
Sergei Kalinin of the Department of Energy’s 91°µÍř knows that seeing something is not the same as understanding it.
The search for a more energy efficient and environmentally friendly method of ammonia production for fertilizer has led to the discovery of a new type of catalytic reaction.
It’s not enough to design new drugs. For drugs to be effective, they have to be delivered safely and intact to affected areas of the body. And drug delivery, much like drug design, is an immensely complex task.
The lighter wand for your gas BBQ, a submarine’s sonar device and the ultrasound machine at your doctor’s office all rely on piezoelectric materials, which turn mechanical stress into electrical energy, and vice versa.
When physicists Georg Bednorz and K. Alex Muller discovered the first high-temperature superconductors in 1986, it didn’t take much imagination to envision the potential technological benefits of harnessing such materials.
With the creation of the Unmanned Aerial Systems Research Center (), 91°µÍř makes available tools and capabilities with applications in environment, energy
By studying hospital occupancy rates in hospitals of countries where data is readily available, 91°µÍř researchers hope to further refine their population distribution and dynamics work.