![magnetic-structure-large.jpg Color map (left) reconstructed image showing the direction of magnetization and the stray magnetic fields in and around a cobalt nanospiral (color wheel indicates magnetization direction) that is only 20 nm in diameter (images taken using high resolution Lorentz microscopy), and (right) tomographic reconstruction showing the 3D shape of the nano-spiral.](/-/media/bes/images/highlights/2014/06/magnetic-structure-large.jpg?h=600&w=766&la=en&hash=CDCC077BB361B9C2FE95074403BCDEC69D1926C923DB29FEFC128F52F0402CA6)
Magnetic Structure of Sculpted Nanospirals
Direct visualization of magnetic structures gives researchers a window into new possibilities at the Nanoscale.
Direct visualization of magnetic structures gives researchers a window into new possibilities at the Nanoscale.
Single palladium atoms convert the surface of an inexpensive metal into an ultra-selective hydrogenation catalyst.
Layers of quantum dots Form “rainbow architecture” that enhances light absorption in a solar cell.
Designing a novel catalyst for the production of hydrogen.
Understanding fundamental chemistry is important for accurate engine modeling.
Discovery of coexisting ordered and disordered catalytic nanoparticles.
Groups of Palladium atoms found to have major effects on electrocatalyst performance.
Computational modelling shows how the shape and motion in a polymer gel can be controlled solely by light.
Electric fields control growth of “sticky” polymer particles.
Precise, predictable positioning of nanoparticles on a liquid crystal droplet.
Linking together two light absorbing pigments to construct a better artificial photosynthesis solar cell.
Soot particle diversity and complexity discovered using ultrafast x-rays at the Linac Coherent Light Source (LCLS).