HEP PROSPECT Characterizes the F... | U.S. DOE Office of Science(SC)
Source: https://science.osti.gov/hep/Highlights/2023/HEP-2023-09-a
Archived: 2026-04-23 17:09
HEP PROSPECT Characterizes the F... | U.S. DOE Office of Science(SC)
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PROSPECT Characterizes the Footprint of Neutrinos
Experiment at Oak Ridge National Laboratory’s High Flux Isotope Reactor precisely measures the antineutrino energy spectrum.
Image courtesy of Oak Ridge National Laboratory; photographer Genevieve Martin
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.
The Science
The neutrino, one of nature’s most elusive and least understood subatomic particles, rarely interacts with matter. That makes precision studies of the neutrino and its antimatter partner, the antineutrino, a challenge. The strongest emitters of
neutrinos
on Earth—nuclear reactors—play a key role in studying these particles. Researchers designed the Precision Reactor Oscillation and Spectrum Experiment (PROSPECT) for detailed studies of electron antineutrinos coming from the core of the
High Flux Isotope Reactor
(HFIR). Now the PROSPECT research collaboration has reported the most precise measurement ever of the energy spectrum of antineutrinos emitted from the fission of uranium-235 (U-235). These results provide scientists with new information about the nature of these particles.
The Impact
Scientists are interested in the properties of the neutrino because they provide a direct test of the
Standard Model of particle physics
. This is the theory describing the interactions between all the fundamental particles in the universe. Suggestions for physics that are not explained by the Standard Model have originated from disagreements between predictions based on the model and data from experiments. These reactor-based experiments have detected fewer neutrinos than expected and found inconsistencies in a small region of the energy spectrum. The new result from the PROSPECT Collaboration directly addresses these inconsistencies. The result does so by providing a new reference energy spectrum. It also provides new constraints on the origin of the disagreements between data and models.
Summary
Experiments based at nuclear reactors have achieved important milestones in neutrino physics, such as the first experimental detection of the particle and the confirmation that neutrinos change between types as they travel. Unique features like high intensity and a compact core of highly enriched U-235 fuel make HFIR an ideal location to continue this long association between reactors and new insight into neutrino properties.
PROSPECT’s collaborators represent more than 60 participants from 13 universities and four national laboratories. They built a novel antineutrino detector system and installed it with extensive, tailored shielding against background at the HFIR research reactor, a Department of Energy (DOE) Office of Science user facility at Oak Ridge National Laboratory. The research focuses on antineutrinos emerging from the fission of U-235. Produced by nuclear beta decay, antineutrinos are
antimatter
-particle counterparts to neutrinos. PROSPECT provided insight into fundamental neutrino physics and is a powerful tool for better understanding nuclear processes in fission reactors. PROSPECT has now reported the most precise measurement of the antineutrino energy spectrum from U-235. Moreover, it provides new constraints on the origin of the observed data-model mismatch. These results have made evident the need for better models describing the production of antineutrinos from fissile isotopes.
Contact
Alfredo Galindo-Uribarri
Oak Ridge National Laboratory
uribarri@ornl.gov
Funding
PROSPECT is supported by the DOE Office of Science, the Heising-Simons Foundation, and the National Science Foundation. The researchers also received support from Yale University, the Illinois Institute of Technology, Temple University, the University of Hawai’i, Brookhaven National Laboratory, the Laboratory Directed Research and Development program at Lawrence Livermore National Laboratory, the National Institute of Standards and Technology, and Oak Ridge National Laboratory. The collaboration also benefits from the support and hospitality of the High Flux Isotope Reactor, a DOE Office of Science User Facility.
Publications
Andriamirado, M.,
et al.
(PROSPECT Collaboration),
Final Measurement of the 235U Antineutrino Energy Spectrum with the PROSPECT-I Detector at HFIR
,
Physical Review Letters
131
, 021802 (2023). [DOI: 10.1103/PhysRevLett.131.021802]
Highlight Categories
Program:
BES
,
HEP
Performer:
University
,
DOE Laboratory
,
SC User Facilities
,
BES User Facilities
,
HFIR
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.
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.
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HEP PROSPECT Characterizes the F... | U.S. DOE Office of Science(SC)
Official websites use .gov
A
.gov
website belongs to an official government organization in the United States.
Secure .gov websites use HTTPS
A
lock
(
) or
https://
means you’ve safely connected to
the .gov website. Share sensitive information only on official,
secure websites.
PROSPECT Characterizes the Footprint of Neutrinos
Experiment at Oak Ridge National Laboratory’s High Flux Isotope Reactor precisely measures the antineutrino energy spectrum.
Image courtesy of Oak Ridge National Laboratory; photographer Genevieve Martin
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.
The Science
The neutrino, one of nature’s most elusive and least understood subatomic particles, rarely interacts with matter. That makes precision studies of the neutrino and its antimatter partner, the antineutrino, a challenge. The strongest emitters of
neutrinos
on Earth—nuclear reactors—play a key role in studying these particles. Researchers designed the Precision Reactor Oscillation and Spectrum Experiment (PROSPECT) for detailed studies of electron antineutrinos coming from the core of the
High Flux Isotope Reactor
(HFIR). Now the PROSPECT research collaboration has reported the most precise measurement ever of the energy spectrum of antineutrinos emitted from the fission of uranium-235 (U-235). These results provide scientists with new information about the nature of these particles.
The Impact
Scientists are interested in the properties of the neutrino because they provide a direct test of the
Standard Model of particle physics
. This is the theory describing the interactions between all the fundamental particles in the universe. Suggestions for physics that are not explained by the Standard Model have originated from disagreements between predictions based on the model and data from experiments. These reactor-based experiments have detected fewer neutrinos than expected and found inconsistencies in a small region of the energy spectrum. The new result from the PROSPECT Collaboration directly addresses these inconsistencies. The result does so by providing a new reference energy spectrum. It also provides new constraints on the origin of the disagreements between data and models.
Summary
Experiments based at nuclear reactors have achieved important milestones in neutrino physics, such as the first experimental detection of the particle and the confirmation that neutrinos change between types as they travel. Unique features like high intensity and a compact core of highly enriched U-235 fuel make HFIR an ideal location to continue this long association between reactors and new insight into neutrino properties.
PROSPECT’s collaborators represent more than 60 participants from 13 universities and four national laboratories. They built a novel antineutrino detector system and installed it with extensive, tailored shielding against background at the HFIR research reactor, a Department of Energy (DOE) Office of Science user facility at Oak Ridge National Laboratory. The research focuses on antineutrinos emerging from the fission of U-235. Produced by nuclear beta decay, antineutrinos are
antimatter
-particle counterparts to neutrinos. PROSPECT provided insight into fundamental neutrino physics and is a powerful tool for better understanding nuclear processes in fission reactors. PROSPECT has now reported the most precise measurement of the antineutrino energy spectrum from U-235. Moreover, it provides new constraints on the origin of the observed data-model mismatch. These results have made evident the need for better models describing the production of antineutrinos from fissile isotopes.
Contact
Alfredo Galindo-Uribarri
Oak Ridge National Laboratory
uribarri@ornl.gov
Funding
PROSPECT is supported by the DOE Office of Science, the Heising-Simons Foundation, and the National Science Foundation. The researchers also received support from Yale University, the Illinois Institute of Technology, Temple University, the University of Hawai’i, Brookhaven National Laboratory, the Laboratory Directed Research and Development program at Lawrence Livermore National Laboratory, the National Institute of Standards and Technology, and Oak Ridge National Laboratory. The collaboration also benefits from the support and hospitality of the High Flux Isotope Reactor, a DOE Office of Science User Facility.
Publications
Andriamirado, M.,
et al.
(PROSPECT Collaboration),
Final Measurement of the 235U Antineutrino Energy Spectrum with the PROSPECT-I Detector at HFIR
,
Physical Review Letters
131
, 021802 (2023). [DOI: 10.1103/PhysRevLett.131.021802]
Highlight Categories
Program:
BES
,
HEP
Performer:
University
,
DOE Laboratory
,
SC User Facilities
,
BES User Facilities
,
HFIR
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.
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.
Contact High Energy Physics
Address
U.S. Department of Energy
SC-25/Germantown Building
1000 Independence Ave., SW
Washington, DC 20585
Phone
Tel(301) 903-3624
Fax(301) 903-2597
Send us a message
sc.hep@science.doe.gov
Read more about
Top
Leaving Office of Science
The link you have requested will take you to a website outside the Office of Science.
Please click the following link to continue:
Thank you for visiting our site. We hope your visit was informative and enjoyable.
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