Building Materials from Spinning Particles
Swarms of synchronized active spinning particles exhibit complex collective behavior, ranging from liquid-like states to dynamic crystals.
Swarms of synchronized active spinning particles exhibit complex collective behavior, ranging from liquid-like states to dynamic crystals.
New approaches shed light on arctic soil microbes and their potential to release greenhouse gases when permafrost thaws.
New measurements offer insights into binding interactions that glue fundamental building blocks of matter together.
Measurements of the electromagnetic properties of radioactive antimony-129 provide unique insight into the nature of the proton-neutron interaction and nuclear shapes.
New research and newly implemented techniques expand scientific understanding of isotopes whose nuclei have the “magic numbers” of less than 82 protons and more than 126 neutrons.
SEER, a new method to rapidly search for proteins involved in rearranging DNA molecules, increases genome editing efficiency.
Environmental factors can change interactions among microorganism communities.
Simple soft materials couple tunable chemical signals to produce distinct energy flows.
Study shows that the strong coupling of photons and spin waves in magnetic materials creates an “exceptional surface” for new phenomena, potentially advancing the field of information processing.
X-ray scattering measures the positions of atoms as they vibrate in a two-dimensional cover sheet.
Novel nanofabrication makes nonlinear photon play possible in 3D.
Scientists reveal oxygen’s hidden talent for filling atomic gaps in 2D semiconductors and the surprising role of electron spin in electronic conductivity