![necces-whittingham-mri-battery-large.jpg Chemical Shift Magnetic Resonance Imaging (MRI) of a lithium battery after charging.](/-/media/bes/images/highlights/2012/02/necces-whittingham-mri-battery-large.jpg?h=649&w=850&la=en&hash=D9D329D7F37C8A0B57C2C76B93E1E7E71AD84B95FF158AB13950113B68AC242A)
Brains, Knees, . . . and now Batteries
Magnetic resonance imaging (MRI) method non-destructively images the chemical and structural changes in a lithium ion battery.
Magnetic resonance imaging (MRI) method non-destructively images the chemical and structural changes in a lithium ion battery.
Antimony atoms with uncoordinated electrons block flow of heat in thermoelectric materials.
Short pulses of light reveal an intrinsic conducting surface that is different from the bulk.
A scalable catalytic process improves the yield of biofuels by 40%.
A single reversible catalyst enables energy to be both stored and released on demand.
New, scalable manufacturing technique grows metal oxide nanosheets with astronomical aspect-ratios, opening the door to intriguing material properties.
Arrays of superconducting islands open up the possibility for tailor-made properties and functionality.
New insights into metal ions at an enzyme’s active site.
Laboratory measurements of “carrier multiplication” verified in real solar energy photovoltaic devices made of tiny quantum dots.
Researchers have captured the first three-dimensional images of changes in shape, composition, and position of individual catalyst particles during electrochemical cycling.
New insights from synchrotron-based studies are helping to assess the potential of new biofuels.
A new spectroscopic “fingerprinting” technique has been developed at a DOE user facility to identify chemical degradation products deep inside a working rechargeable battery.