HEP Highlights

In nuclear beta decay an up quark ‘u’ in a proton converts into an up down quark ‘d,’ turning the proton into a neutron and emitting a positron and a neutrino. This work affects interpretation of beta decay measurements across the chart of nuclides.

March 26, 2025

New Precise Calculation of Nuclear Beta Decays Paves the Way to Uncover Physics Beyond the Standard Model

Theorists identify new effects needed to compute the nuclear beta decay rate with a precision of a few parts in ten thousand.

The Belle II experiment at the SuperKEKB accelerator measures particle interactions with extreme precision. Collisions of electron and positron beams create the high-energy environment needed to produce subatomic particles that do not otherwise exist in nature.

November 1, 2024

Belle II Detector Produces World’s Most Precise Measurements of Subatomic Particle Lifetimes

Particle lifetime measurements with early data from the Belle II experiment at the SuperKEKB accelerator demonstrate the experiment’s high precision.

Researchers have long thought pure niobium superconducting radiofrequency cavities were best for particle accelerators. Researchers are now using a toolkit to learn how to add impurities to the cavities to make them smoother—and more efficient.

September 18, 2024

Smoother Surfaces Make for Better Particle Accelerators

An enhanced topographic analysis toolkit for forecasting and improving particle accelerator performance is helping scientists build better accelerators.

The High Flux Isotope Reactor, a Department of Energy Office of Science user facility, is the site of PROSPECT, an experiment to study the properties of the neutrino.

October 24, 2023

PROSPECT Characterizes the Footprint of Neutrinos

Experiment at Oak Ridge National Laboratory’s High Flux Isotope Reactor precisely measures the antineutrino energy spectrum.

Understanding neutrino (?) oscillations depends on understanding ?-nucleus (and ?-nucleon) interactions. Modern nuclear theory predictions of the ?-nucleon interaction (top band, data points) are larger than those inferred from old data (lower, red band).

August 18, 2023

In Preparation for DUNE, Scientists Examine Modern Nuclear Theory for Neutrino Oscillation Physics

Modern nuclear theory predicts that nucleons appear less “squishy” when probed with neutrinos than was previously inferred from experimental data.

A magnetic focusing "horn" that scientists used to produce the neutrinos in Fermi National Accelerator Laboratory's NuMI beam. This method made this first-ever image of the proton using neutrinos.

March 20, 2023

Imaging the Proton with Neutrinos

The MINERvA experiment in the NuMI beam at Fermilab has made the first accurate image of the proton using neutrinos instead of light as the probe.

Contours of magnetic fields that emerge a result of self-organization of microscopic currents resulting from the Weibel instability in a carbon dioxide laser-produced plasma probed by an ultrashort relativistic electron beam.

January 17, 2023

The Mechanism Of Cosmic Magnetic Fields Explored in the Laboratory

A novel experiment sheds new light on a possible mechanism that may seed magnetic fields for the galactic dynamo.

Researchers demonstrated a new quantum error mitigation approach by simulating the evolution of a chain of six spins (top). The mitigated results are much closer to the exact results than the original measured data from the quantum computer (bottom).

May 4, 2022

New Error Mitigation Approach helps Quantum Computers Level Up

Noise estimation circuits, in conjunction with other error mitigation methods, produce reliable results for quantum computer-based materials simulations.