A new quantitative understanding of how, at what distance, and in what shape zinc oxide nanoparticles come together while separated by liquid.
A newly designed X-ray oscillator may enable atomic level precision with intense X-ray pulses.
A new quantitative understanding of how, at what distance, and in what shape zinc oxide nanoparticles come together while separated by liquid.
Scientists use a machine learning algorithm to reduce tuning time of a dozen instruments at once.
A novel terahertz laser achieves the performance goals critical for new applications in sensing and imaging.
An X-ray image taken with a novel X-ray wavefront imager results in high precision measurements of intensity and direction of the X-ray beam.
Research uses directed gas phase preparation of two carbenes, triplet pentadiynylidene and singlet ethynylcyclopropenylidene
Observation of impulsive stimulated X-ray Raman scattering with attosecond soft X-ray pulses.
Advanced techniques reveal how defects in nanoscale crystals affect how solar photovoltaics perform.
Harnessing the intensity of a terahertz laser pulse brings the resolution of electron scattering closer to the scale of electron and proton motion.
Crystals grown from layers of atoms arrange themselves on semiconductor surfaces to add new capabilities.
Neutron scattering and isotopic substitution techniques reveal how to block vibrations that could leak heat from a photovoltaic cell.
