Construction workers have carried out the first underground blasting for the Long-Baseline Neutrino Facility, which will provide the space, infrastructure and particle beam for the international Deep Underground Neutrino Experiment. This prep work paves the way for removing more than 800,000 tons of rock to make space for the gigantic DUNE detector a mile underground.
The Department of Energy’s Office of Science has selected three Fermilab scientists to receive the 2020 DOE Early Career Research Award, now in its 11th year. The prestigious award is designed to bolster the nation’s scientific workforce by providing support to exceptional researchers during the crucial early years, when many scientists do their most formative work.
The biggest conference in neutrino physics kicks off on June 22, with two weeks of talks dedicated to one intriguing particle.
From fixing up furniture as a kid to testing particle accelerator components at the lab and woodworking in his garage, Dave Burk has a knack for solving problems with his hands.
An international team of theoretical physicists have published their calculation of the anomalous magnetic moment of the muon. Their work expands on a simple yet richly descriptive equation that revolutionized physics almost a century ago and that may aid scientists in the discovery of physics beyond the Standard Model. Now the world awaits the result from the Fermilab Muon g-2 experiment.
Engineers from five countries are coordinating the design of the large cryomodules that will enable the new PIP-II accelerator at Fermilab to generate protons for the world’s most powerful beam of neutrinos, in support of the international Deep Underground Neutrino Experiment.
Quantum computing will affect the future of every area of science, creating the need for a quantum-fluent workforce. In collaboration with two high school teachers, a group of Fermilab theorists has developed a quantum computing course for high school students. With this course, Fermilab scientists are breaking new ground in both quantum computing research and supporting the competitiveness of the STEM workforce in the quantum era.
A good dark matter detector has a lot in common with a good teleconference setup: You need a sensitive microphone and a quiet room. The SENSEI experiment has demonstrated world-leading sensitivity and the low background needed for an effective search for low-mass dark matter.
Fermilab is currently upgrading its accelerator complex to produce the world’s most powerful beam of high-energy neutrinos. To generate these particles, the accelerators will send an intense beam of protons traveling near the speed of light through a maze of particle accelerator components before passing through metallic “windows” and colliding with a stationary target. Researchers are testing the endurance of windows made of a titanium alloy, exposing samples to high-intensity proton beams to see how well the material will perform.
If you live in the Chicago suburbs and have ever taken a walk on the Fermilab hike-and-bike trail along Batavia Road, you’ve probably noticed large trees with long, slender bean pods, which — even after they fall to the ground — are ignored by wildlife. Not that long ago, mammoths, mastodons and giant ground sloths roamed the Fermilab grounds and feasted on these bean pods, along with the fruit of two additional species that still can be found growing on site.