New insights reveal details of how strange matter forms.
Researchers design ultra-low radiation cables to reduce background noise for highly sensitive nuclear decay and dark matter detectors.
An almost-bound isotope of oxygen undergoes four-neutron decay that challenges theory.
Experiments find increased temperatures and carbon dioxide rapidly altered peatland carbon stocks, highlighting peatlands’ vulnerability to climate change.
![Composite of geopotential heights [m] (contours) and anomalies (colors) at 700 Hectopascal (hPa) of air pressure for each SOM node. These nodes help unpack how high- and low-pressure systems and other climate factors contribute to Texas rainstorms.](/-/media/ber/images/highlights/2024/High-Pressure-Systems.png?h=844&w=964&la=en&hash=810D3A676C1F7B8F0ABA215C5C39868B405F98E694DB597BB96940FE74D7CAE9)
AI reveals relationships between weather systems and cloud physics.
Voronoi tessellation meshes focus on sea ice areas of interest and reduce computer resource needs.
The first results from the MAJORANA experiment dramatically improve current limits on this rare isotope’s decay.
Nuclear physicists have found the location of matter inside the proton that comes from the strong force - a fundamental force that holds protons together.
The Project 8 and He6-CRES collaborations use a new technique to set an upper limit on neutrino mass and prepare to test the nature of the weak force.
Improving genome engineering with quantum biology and artificial intelligence.
The first application of High-Throughput Chromosome Conformation Capture (Hi-C) Metagenome Sequencing to soil captures phage-host interactions at the time of sampling.
High resolution isotope analysis of the algal microbiome identifies ecological strategies not predicted by genome content.
