GlueX

Last updated November 18, 2023

GlueX is a particle physics experiment located at the Thomas Jefferson National Accelerator Facility (JLab) accelerator in Newport News, Virginia. Its primary purpose is to better understand the nature of confinement in quantum chromodynamics (QCD) by identifying a spectrum of hybrid and exotic mesons generated by the excitation of the gluonic field binding the quarks. Such mesonic states are predicted to exist outside of the well-established quark model, but none have been definitively identified by previous experiments. A broad high-statistics survey of known light mesons up to and including the $J/\psi$ is also underway.

Experimental apparatus

The experiment uses photoproduction (that is, the scattering of a real photon on a nucleon) to produce mesonic states. Unlike previous similar experiments, it uses linearly polarized photons, which allows the analysis of accumulated events for certain polarization observables that are thought to make identification of exotic states feasible.

The GlueX detector was installed in the new Hall D (the fourth such hall at JLab) as part of the accelerator's upgrade to 12 GeV energy.^[1] GlueX began its first commissioning run in 2014, and first received 12 GeV electrons in 2015, the highest energy available at the CEBAF accelerator. Publication-quality physics data was accumulated during multi-weeks runs starting in 2016, continuing into 2023 and beyond.

The detector is based on a solenoidal hermetic detector optimized for tracking of charged particles (electron, pions, kaons, and protons) and detection of neutral particles (primarily photons). Figure 1 shows the detector.

GlueX uses the coherent bremsstrahlung technique to produce a linearly polarized photon beam. In order to reach the optimal photon energy near 9 GeV for this mapping of the exotic spectrum, 12 GeV electrons are required and are provided by the CEBAF accelerator at Jefferson Lab.

In 2018, improved kaon/pion separation capability will be established with the addition of a quartz-based differential Cherenkov light detector ("DIRC").

Program

The goal of the GlueX experiment is to search for and study hybrid mesons. Hybrid mesons, and in particular exotic hybrid mesons, provide the ideal laboratory for testing QCD in the confinement regime since these mesons explicitly manifest the gluonic degrees of freedom. Photoproduction is expected to be particularly effective in producing and identifying these states. At the same time these data will be used to study the spectrum of conventional mesons, including the poorly-understood excited vector mesons and strangeonium.

The search for new mesonic states requires very specialized analysis methods since such states are rare and must be established through their decay to lighter and longer-lived particles. By examining the energy and angular distributions of produced particles through partial wave analysis, the production and decay of all intermediate states can be reconstructed. The quantum numbers of the intermediate states can be established by this method. These quantum numbers include the spin angular momentum (J), parity (P), and charge conjugation parity (C). Many hybrid states are expected to have quantum number combinations that are the same as conventional quark-model mesons. But the quark model predicts precisely how many such states should exist, and it is expected that an "overpopulation" of certain combinations may herald hybrid states. That is, identified intermediate states with quantum numbers permitted by the quark model may be "hybrids" that contain gluonic excitation, and can be established as such if their number and pattern of mass distribution are not explained within the simple quark model. States with quantum numbers that are strictly forbidden by the naive quark model are said to be "exotic" and, if found experimentally, immediately demonstrate gluonic excitation.

A list of the scientific and technical papers resulting from the GlueX program is linked at the bottom of this article. The range of questions addressed is broad, as seen in the following list of topics of present and possible future runs:

Exploration of the light meson spectrum
Partial wave decomposition of various reaction channels to identify underlying mesonic structure
Threshold photoproduction of charm and the search for associated pentaquarks
High-statistics study of eta and eta' meson production, asymmetries, and decays
Photoproduction of baryon-antibaryon pairs
Search for photoproduced cascade resonances beyond the few well-known ones
Search for "leptophobic" states beyond the Standard Model
Eta meson decay width measurement via the Primakoff effect
Measurement of the polarizability of pions, as a test of low-energy QCD

Collaborating institutions

Cumulative since 2003.

Universities

Arizona State University - Tempe, AZ
Carnegie Mellon University - Pittsburgh, PA
Catholic University of America - Washington, DC
Christopher Newport University - Newport News, VA
Florida International University - Miami, FL
Florida State University - Tallahassee, FL
George Washington University - Washington, DC
Indiana University - Bloomington, IN
Massachusetts Institute of Technology - Cambridge, MA
Norfolk State University - Norfolk, VA
North Carolina A&T State - Greensboro, NC
Northwestern University - Chicago, IL
Old Dominion University - Norfolk, VA
Rensselaer Polytechnic Institute - Troy, NY
The College of William and Mary - Williamsburg, VA
Tomsk State University - Tomsk, Russia
Universidad Técnica Federico Santa María - Valparaíso, Chile
University of Athens - Athens, Greece
University of Connecticut - Storrs, CT
University of Glasgow - Glasgow, Scotland
University of North Carolina - Wilmington, NC
University of Massachusetts - Amherst, MA
University of Regina - Regina, Canada
University of Virginia - Charlottesville, VA
Wuhan University - Wuhan, China

Laboratories

Budker Institute of Nuclear Physics - Novosibirsk, Russia
GSI - Darmstadt, Germany
Institute for High Energy Physics - Protvino, Russia
Institute of High Energy Physics(IHEP) - Beijing, China
Nuclear Physics Institute, Moscow State University - Moscow, Russia
Thomas Jefferson National Accelerator Facility - Newport News, VA
Yerevan Physics Institute - Yerevan, Armenia

Related Research Articles

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In particle physics, XYZ particles are recently-discovered heavy mesons whose properties do not appear to fit the standard picture of charmonium and bottomonium states. They are therefore types of exotic mesons. The term arises from the names given to some of the first such particles discovered: X(3872), Y(4260) and Z_c(3900), although the symbols X and Y have since been deprecated by the Particle Data Group.

Volker D. Burkert is a German physicist, academic and researcher. He is a Principal Staff Scientist at the Thomas Jefferson National Accelerator Facility at Jefferson Lab (JLab) in Newport News, Virginia (USA). He has made major contributions to the design of the CEBAF Large Acceptance Spectrometer (CLAS) that made it suitable for high luminosity operation in experiments studying spin-polarized electron scattering.

References

↑ 12 GeV Upgrade: Future Science at Jefferson Lab - Project Information

External links

A list of GlueX publications from INSPIRE-HEP
Official Hall-D web page at Jefferson Lab
GlueX.org: Collaboration website
GlueX experiment record on INSPIRE-HEP

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[1] 12 GeV Upgrade: Future Science at Jefferson Lab - Project Information

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