Story tips from the Department of Energy’s Oak Ridge National Laboratory, October 2017


Credit: Liam Collins/Oak Ridge National Laboratory, US Dept. of Energy

Cybersecurity – Guarding autonomous vehicles

A new Oak Ridge National Laboratory-developed method promises to protect connected and autonomous vehicles from possible network intrusion. Researchers built a prototype plug-in device designed to alert drivers of vehicle cyberattacks. The prototype is coded to learn regular timing of signals in the communications network of an individual vehicle and detect abnormalities in timing frequency that could indicate a network intrusion or malicious software. Initial prototype testing in ORNL's Vehicle Security Laboratory demonstrated near-perfect intrusion detection rates. "This is a first step toward developing solutions to protect vehicles," says ORNL's Bobby Bridges. "Ideally, accurate detection capabilities will facilitate ways to contain or block network intrusions in real-time on the road." [Contact: Kim Askey, 865-946-1861; [email protected]]


Caption: ORNL's Frank Combs and Michael Starr of the U.S. Armed Forces (driver) work in ORNL's Vehicle Security Laboratory to evaluate a prototype device that can detect network intrusions in all modern vehicles. Credit: Carlos Jones/Oak Ridge National Laboratory, U.S. Dept. of Energy

Microscopy – Breaking the time barrier

Oak Ridge National Laboratory scientists have developed a technique for making ultrafast measurements using atomic force microscopy, which previously could only investigate slow or static material structures and functions. In AFM, a rastering probe maps a material's surface and captures physical and chemical properties. But the probe is slow to respond to what it detects. This temporal bottleneck inspired ORNL's fast free force recovery technique, which uses advanced machine learning algorithms to analyze instantaneous tip motion to produce high-resolution images 3,500 times faster than standard AFM detection methods. "This new approach can probe fast processes, such as charge screening, ionic transport and electrochemical phenomena, which were previously inaccessible with traditional AFM," said ORNL's Liam Collins, first author of a publication describing the technique. [Dawn Levy, 865-576-6448; [email protected]]


Caption: ORNL researchers demonstrated ultrafast mapping of surface voltage dynamics because of ion migration induced by an electric field in a perovskite solar-cell device. Credit: Liam Collins/Oak Ridge National Laboratory, U.S. Dept. of Energy


Media Contact

Sara Shoemaker
[email protected]

Original Source