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![A simulation shows the path for the collision of a krypton ion (blue) with a defected graphene sheet and subsequent formation of a carbon vacancy (red). Red shades indicate local strain in the graphene. Image credit: Kichul Yoon, Penn State A simulation shows the path for the collision of a krypton ion (blue) with a defected graphene sheet and subsequent formation of a carbon vacancy (red). Red shades indicate local strain in the graphene. Image credit: Kichul Yoon, Penn State](/sites/default/files/styles/list_page_thumbnail/public/news/images/graphene_defect1.jpg?itok=2KdyjJb0)
![Superhydrophobic water droplets Superhydrophobic water droplets](/sites/default/files/styles/list_page_thumbnail/public/Superhydrophobic%20water%20droplets.jpg?itok=4iJXp2Ql)
![ORNL’s Michael Manley led a study to discover the key to the success of modern materials used in ultrasound machines and other piezoelectric devices. ORNL’s Michael Manley led a study to discover the key to the success of modern materials used in ultrasound machines and other piezoelectric devices.](/sites/default/files/styles/list_page_thumbnail/public/news/images/2016-P04731.jpg?itok=b-quvxzq)
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. In 1997, researchers developed piezoelectric...
![To direct-write the logo of the Department of Energy’s Oak Ridge National Laboratory, scientists started with a gray-scale image. To direct-write the logo of the Department of Energy’s Oak Ridge National Laboratory, scientists started with a gray-scale image.](/sites/default/files/styles/list_page_thumbnail/public/news/images/ORNL%20Leaf%20Logo_No%20Scale_Green_v2.jpg?itok=rpIXT_ko)
![Paul Kent of Oak Ridge National Laboratory directs the Center for Predictive Simulation of Functional Materials. Paul Kent of Oak Ridge National Laboratory directs the Center for Predictive Simulation of Functional Materials.](/sites/default/files/styles/list_page_thumbnail/public/news/images/2016-P04277.jpg?itok=jOJBdTf5)
The US Department of Energy announced today that it will invest $16 million over the next four years to accelerate the design of new materials through use of supercomputers.
![A 32-face 3-D truncated icosahedron mesh was created to test the simulation’s ability to precisely construct complex geometries. A 32-face 3-D truncated icosahedron mesh was created to test the simulation’s ability to precisely construct complex geometries.](/sites/default/files/styles/list_page_thumbnail/public/nn-2016-021085_0009_0.jpeg?itok=ZRBSAZox)
![ORNL will lend computational resources such as its Titan supercomputer to support the Cancer Moonshot effort. ORNL will lend computational resources such as its Titan supercomputer to support the Cancer Moonshot effort.](/sites/default/files/styles/list_page_thumbnail/public/news/images/2012-P03136.jpg?itok=THyiUKYH)
The Department of Energy’s Oak Ridge National Laboratory will add its computational know-how to the battle against cancer through several new projects recently announced at the White House Cancer Moonshot Summit.
![OLCF Vimeo Screenshot OLCF Vimeo Screenshot](/sites/default/files/styles/list_page_thumbnail/public/OLCF_Vimeo_screenshot.jpg?itok=4K2fxSf1)
While trying to fatten the atom in 1938, German chemist Otto Hahn accidentally split it instead. This surprising discovery put modern science on the fast track to the atomic age and to the realization of technologies with profound potential for great harm or great help. Altho...
![ORNL’s Huiyuan Zhu places a sample of boron nitride, or “white graphene,” into a furnace as part of a novel, nontoxic gas exfoliation process to separate 2D nanomaterials. ORNL’s Huiyuan Zhu places a sample of boron nitride, or “white graphene,” into a furnace as part of a novel, nontoxic gas exfoliation process to separate 2D nanomaterials.](/sites/default/files/styles/list_page_thumbnail/public/01%20BN%20Gas%20Exfoliation%20Process_0.jpg?itok=xTDiW79S)
![The image above shows the chain of the studied calcium isotopes. The “doubly magic” isotopes with mass numbers 40 (Ca-40) and 48 (Ca-48) exhibit equal charge radii. The first measurement of the charge radius in Ca-52 yielded an unexpectedly large result. The image above shows the chain of the studied calcium isotopes. The “doubly magic” isotopes with mass numbers 40 (Ca-40) and 48 (Ca-48) exhibit equal charge radii. The first measurement of the charge radius in Ca-52 yielded an unexpectedly large result.](/sites/default/files/styles/list_page_thumbnail/public/Hagen%20Image%5B2%5D.jpg?itok=9x4IORoE)
For decades nuclear physicists have tried to learn more about which elements, or their various isotopes, are “magic.” This is not to say that they display supernatural powers. Magic atomic nuclei are composed of “magic” numbers of protons and neutrons—collectively called nucleons—such as 2, 8, 20, and 28.