With the caverns now open, detectors will start to make their way down over the next year to help with LBNF/DUNE.

A massive milestone was celebrated on the international Long-Baseline Neutrino Facility/Deep Underground Neutrino Experiment that will tell us more about the universe and how it works.

How I spent my summer learning about enigmatic particles that pass right through me by the billions every second!

Pantaleo Raimondi’s illustrious career brought him to some of the world’s most prestigious particle physics institutions. In January, Raimondi continued this journey as he took over the role of project director for Fermilab’s newest, more powerful particle accelerator.

During a ceremony at ICHEP, Ngadiuba’s contributions to ultra-fast machine learning techniques and anomaly detection were recognized by the International Union of Pure and Applied Physics.

Physicists use large particle detectors filled with liquid argon to study neutrinos. Brazilian scientists discovered that a commercially available material can significantly reduce the amount of nitrogen in liquid argon, which improves the detection of neutrino interactions.

Scientists at Fermilab and University of Chicago used a superconducting qubit to prepare a microwave cavity in a special state to stimulate photons. They hope this technology will help detect the existence of dark matter.

Xiao Luo, a professor at UC Santa Barbara, was acknowledged by the Sloan Foundation for her work on MicroBooNE, the Short Baseline Near Detector and DUNE.

Neutrino Day attracted thousands of people from throughout the country to participate in Lead’s annual science festival.

New experimental results show particles called muons can be corralled into beams suitable for high-energy collisions, paving the way for new physics.