Scientists have found a way to significantly boost “blue energy,” which generates electricity from the mixing of saltwater and freshwater. By coating nanopores with lipid molecules that create a friction-reducing water layer, they enabled ions to pass through much more efficiently while keeping the process highly selective. Their prototype membrane produced about two to three times more power than current technologies. The discovery could help bring osmotic energy closer to becoming a practical renewable power source.

Thermal treatment approaches can remediate solids contaminated by per- and polyfluoroalkyl substances (PFAS), but are energy-intensive and create products of incomplete destruction. This Review discusses these approaches and the use of additives to lower reaction temperatures and drive complete destruction of PFAS.

High-temporal-resolution fluorescence measurements reveal how quickly proteins cross energy barriers separating unfolded and folded states.

Proteins are the active molecules of life. To carry out their functions, they adopt specific structures, or “folds.” Biophysicists have long been fascinated by the “protein-folding problem”: How does the sequence of amino-acid building blocks encode the protein’s ultimate fold, and how can folding occur so quickly and reliably? The folding process can be understood as a diffusive random walk through the large space of possible configurations, culminating in the crossing of an energy barrier to reach the folded state. The time spent exploring unfolded configurations can span many orders of magnitude and has been measured with various experimental techniques. By contrast, the comparatively short time to ultimately cross the energy barrier—known as the transition-path time—had never been measured in a naturally occurring protein under biologically relevant conditions.