Catching a glimpse of the breaking and formation of chemical bonds in ultracold chemical reactions.
New finding may help explain why we develop chronic diseases and cancer as we age…and even why food decomposes over time.
Researchers create novel metallabiphenylene analogues, advancing a key concept in organic chemistry.
Collaboration between experiment and theory expands fundamental understanding of the chemistry of exotic radioactive heavy elements.
Local scaling self-interaction correction (LSIC) overcomes long-standing problems for accurate simulation of chemical reactions from start to finish.
Novel isotope tracking brings nanoscale chemistry into view
Molecular cage to trap chloride could help reduce rising level of salt contaminants flowing into freshwater streams and lakes across the United States.
Understanding how polycyclic aromatic hydrocarbons form can help scientists better understand the origin and evolution of carbon in our galaxy
A new catalyst design meets cost, activity, and durability goals by leveraging ultralow loadings of platinum with platinum-free supports.
New approach to studying ions more accurately predicts behavior, providing insights for biological systems, environmental processes, and materials development.
Expanding our understanding of the structure and decay properties of some of the most exotic elements.
Read more about Building a Scale to Weigh Superheavy Elements
New method could enable studying the fastest interactions of ultrabright X-rays with matter, a vital way of learning about chemical reactions.
