Breakthrough measurement elucidates neutrino interactions
Date:
April 12, 2022
Source:
DOE/Brookhaven National Laboratory
Summary:
Physicists studying ghost-like particles called neutrinos
from the international MicroBooNE collaboration have reported
a first-of-its-kind measurement: a comprehensive set of the
energy-dependent neutrino-argon interaction cross sections. This
measurement marks an important step towards achieving the scientific
goals of next-generation of neutrino experiments--namely, the Deep
Underground Neutrino Experiment (DUNE).
FULL STORY ========================================================================== Physicists studying ghost-like particles called neutrinos from the international MicroBooNE collaboration have reported a first-of-its-kind measurement: a comprehensive set of the energy-dependent neutrino-argon interaction cross sections. This measurement marks an important step
towards achieving the scientific goals of next-generation of neutrino experiments - - namely, the Deep Underground Neutrino Experiment (DUNE).
========================================================================== Neutrinos are tiny subatomic particles that are both famously elusive
and tremendously abundant. While they endlessly bombard every inch
of Earth's surface at nearly the speed of light, neutrinos can travel
through a lightyear's worth of lead without ever disturbing a single
atom. Understanding these mysterious particles could unlock some of the
biggest secrets of the universe.
The MicroBooNE experiment, located at the U.S. Department of Energy's
(DOE) Fermi National Accelerator Laboratory, has been collecting data on neutrinos since 2015, partially as a testbed for DUNE, which is currently
under construction. To identify elusive neutrinos, both experiments use a low-noise liquid-argon time projection chamber (LArTPC) -- a sophisticated detector that captures neutrino signals as the particles pass through
frigid liquid argon kept at -303 degrees Fahrenheit. MicroBooNE physicists
have been refining LArTPC techniques for large-scale detectors at DUNE.
Now, a team effort led by scientists at DOE's Brookhaven National
Laboratory, in collaboration with researchers from Yale University and Louisiana State University, has further refined those techniques by
measuring the neutrino- argon cross section. Their work published today
in Physical Review Letters.
"The neutrino-argon cross section represents how argon nuclei respond
to an incident neutrino, such as those in the neutrino beam produced by MicroBooNE or DUNE," said Brookhaven Lab physicist Xin Qian, leader of Brookhaven's MicroBooNE physics group. "Our ultimate goal is to study
the properties of neutrinos, but first we need to better understand how neutrinos interact with the material in a detector, such as argon atoms."
One of the most important neutrino properties that DUNE will investigate
is how the particles oscillate between three distinct "flavors": muon
neutrino, tau neutrino, and electron neutrino. Scientists know that
these oscillations depend on neutrinos' energy, among other parameters,
but that energy is very challenging to estimate. Not only are neutrino interactions extremely complex in nature, but there is also a large
energy spread within every neutrino beam.
Determining the detailed energy-dependent cross sections provides
physicists with an essential piece of information to study neutrino oscillations.
========================================================================== "Once we know the cross section, we can reverse the calculation to
determine the average neutrino energy, flavor, and oscillation properties
from a large number of interactions," said Brookhaven Lab postdoc Wenqiang
Gu, who led the physics analysis.
To accomplish this, the team developed a new technique to extract the
detailed energy-dependent cross section.
"Previous techniques measured the cross section as a function of
variables that are easily reconstructed," said London Cooper-Troendle,
a graduate student from Yale University who is stationed at Brookhaven
Lab through DOE's Graduate Student Research Program. "For example, if
you are studying a muon neutrino, you generally see a charged muon coming
out of the particle interaction, and this charged muon has well-defined properties like its angle and energy. So, one can measure the cross
section as a function of the muon angle or energy.
But without a model that can accurately account for "missing energy,"
a term we use to describe additional energy in the neutrino interactions
that can't be attributed to the reconstructed variables, this technique
would require experiments to act conservatively." The research team
led by Brookhaven sought to validate the neutrino energy reconstruction
process with unprecedented precision, improving theoretical modeling
of neutrino interactions as needed for DUNE. To do so, the team applied
their expertise and lessons learned from previous work on the MicroBooNE experiment, such as their efforts in reconstructing interactions with
different neutrino flavors.
"We added a new constraint to significantly improve the mathematical
modeling of neutrino energy reconstruction," said Louisiana State
University assistant professor Hanyu Wei, previously a Goldhaber fellow
at Brookhaven.
==========================================================================
The team validated this newly constrained model against experimental
data to produce the first detailed energy-dependent neutrino-argon cross section measurement.
"The neutrino-argon cross section results from this analysis are able
to distinguish between different theoretical models for the first time,"
Gu said.
While physicists expect DUNE to produce enhanced measurements of the cross section, the methods developed by the MicroBooNE collaboration provide
a foundation for future analyses. The current cross section measurement
is already set to guide additional developments on theoretical models.
In the meantime, the MicroBooNE team will focus on further enhancing its measurement of the cross section. The current measurement was done in
one dimension, but future research will tackle the value in multiple
dimensions - - that is, as a function of multiple variables -- and
explore more avenues of underlying physics.
This work was supported by the DOE Office of Science.
========================================================================== Story Source: Materials provided by
DOE/Brookhaven_National_Laboratory. Note: Content may be edited for
style and length.
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(15) DOI: 10.1103/PhysRevLett.128.151801 ==========================================================================
Link to news story:
https://www.sciencedaily.com/releases/2022/04/220412141027.htm
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