Glueball

Template:Short description Template:Standard model of particle physics In particle physics, a glueball (also gluonium, gluon-ball) is a hypothetical composite particle.<ref>Template:Cite journal</ref> It consists solely of gluon particles, without valence quarks. Such a state is possible because gluons carry color charge and experience the strong interaction between themselves. Glueballs are extremely difficult to identify in particle accelerators, because they mix with ordinary meson states.<ref> Template:Cite journal</ref><ref>Glueball on arxiv.org Template:Webarchive</ref> In pure gauge theory, glueballs are the only states of the spectrum and some of them are stable.<ref>Template:Cite book</ref>

Theoretical calculations show that glueballs should exist at energy ranges accessible with current collider technology. However, due to the aforementioned difficulty (among others), they have so far not been observed and identified with certainty,<ref name="ochs">Template:Cite journal</ref> although phenomenological calculations have suggested that an experimentally identified glueball candidate, denoted f₀(1710), has properties consistent with those expected of a Standard Model glueball.<ref>Template:Cite journal</ref>

The prediction that glueballs exist is an essential prediction of QCD as part of the Standard Model of particle physics that has not yet been unambiguously confirmed experimentally.<ref>Template:Citation</ref>

Experimental evidence was announced in 2021, by the TOTEM collaboration at the LHC in collaboration with the DØ collaboration at the former Tevatron collider at Fermilab, of odderon (a composite gluonic particle with odd C-parity) exchange. This exchange, associated with a quarkless three-gluon vector glueball, was identified in the comparison of proton–proton and proton–antiproton scattering.<ref>Template:Cite journal</ref><ref>Template:Cite journal</ref><ref>Template:Cite journal</ref> In 2024, the X(2370) particle was determined to have mass and spin parity consistent with that of a glueball.<ref>Template:Cite journal</ref> However, other exotic particle candidates such as a tetraquark could not be ruled out.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

{{ safesubst:#invoke:Unsubst||date=__DATE__ |$B= {{ safesubst:#invoke:Unsubst||date=__DATE__ |$B= Template:Ambox }} }} In principle, it is theoretically possible for all properties of glueballs to be calculated exactly and derived directly from the equations and fundamental physical constants of quantum chromodynamics (QCD) without further experimental input. So, the predicted properties of these hypothetical particles can be described in exquisite detail using only Standard Model physics that have wide acceptance in the theoretical physics literature. But, there is considerable uncertainty in the measurement of some of the relevant key physical constants, and the QCD calculations are so difficult that solutions to these equations are almost always numerical approximations (calculated using several very different methods). This can lead to variation in theoretical predictions of glueball properties, like mass and branching ratios in glueball decays.

{{ safesubst:#invoke:Unsubst||date=__DATE__ |$B= {{ safesubst:#invoke:Unsubst||date=__DATE__ |$B= Template:Ambox }} }} Theoretical studies of glueballs have focused on glueballs consisting of either two gluons or three gluons, by analogy to mesons and baryons that have two and three quarks respectively. As in the case of mesons and baryons, glueballs would be QCD color charge neutral. The baryon number of a glueball is zero.

{{ safesubst:#invoke:Unsubst||date=__DATE__ |$B= {{ safesubst:#invoke:Unsubst||date=__DATE__ |$B= Template:Ambox }} }} Double-gluon glueballs can have total angular momentum Template:Math (which are either scalar or pseudo-scalar) or Template:Math (tensor). Triple-gluon glueballs can have total angular momentum Template:Math (vector boson) or Template:Math (third-order tensor boson). All glueballs have integer total angular momentum that implies that they are bosons rather than fermions.

Glueballs are the only particles predicted by the Standard Model with total angular momentum (Template:Mvar) (sometimes called "intrinsic spin") that could be either 2 or 3 in their ground states, although mesons made of two quarks with Template:Math and Template:Math with similar masses have been observed and excited states of other mesons can have these values of total angular momentum.

All glueballs would have an electric charge of zero, as gluons themselves do not have an electric charge.Template:Cn

Glueballs are predicted by quantum chromodynamics to be massive, despite the fact that gluons themselves have zero rest mass in the Standard Model. Glueballs with all four possible combinations of quantum numbers Template:Math (spatial parity) and Template:Math (charge parity) for every possible total angular momentum have been considered, producing at least fifteen possible glueball states including excited glueball states that share the same quantum numbers but have differing masses with the lightest states having masses as low as Template:Val (for a glueball with quantum numbers Template:Math, or equivalently Template:Math), and the heaviest states having masses as great as almost Template:Val (for a glueball with quantum numbers Template:Math, or Template:Math).<ref name="ochs"/>

These masses are on the same order of magnitude as the masses of many experimentally observed mesons and baryons, as well as to the masses of the tau lepton, charm quark, bottom quark, some hydrogen isotopes, and some helium isotopes.Template:Cn

Just as all Standard Model mesons and baryons, except the proton, are unstable in isolation, all glueballs are predicted by the Standard Model to be unstable in isolation, with various QCD calculations predicting the total decay width (which is functionally related to half-life) for various glueball states. QCD calculations also make predictions regarding the expected decay patterns of glueballs.<ref name="slac.stanford.edu">{{#invoke:citation/CS1|citation |CitationClass=web }}</ref><ref>Template:Cite arXiv</ref> For example, glueballs would not have radiative or two photon decays, but would have decays into pairs of pions, pairs of kaons, or pairs of eta mesons.<ref name="slac.stanford.edu"/>

File:Feynmann Diagram Glueball-to-Pion.svg

Standard Model glueballs are extremely ephemeral (decaying almost immediately into more stable decay products) and are only generated in high energy physics. Thus in the natural conditions found on Earth that humans can easily observe, glueballs arise only synthetically. They are scientifically notable mostly because they are a testable prediction of the Standard Model, and not because of phenomenological impact on macroscopic processes, or their engineering applications.

Lattice QCD provides a way to study the glueball spectrum theoretically and from first principles. Some of the first quantities calculated using lattice QCD methods (in 1980) were glueball mass estimates.<ref>Template:Cite journal</ref> Morningstar and Peardon computed the masses of the lightest glueballs in QCD without dynamical quarks in 1999.<ref>Template:Cite journal</ref> The three lowest states are tabulated below. The presence of dynamical quarks would slightly alter these data, but also makes the computations more difficult. Since that time calculations within QCD (lattice and sum rules) find the lightest glueball to be a scalar with mass in the range of about Template:Val.<ref name="ochs"/> Lattice predictions for scalar and pseudoscalar glueballs, including their excitations, were confirmed by Dyson–Schwinger/Bethe–Salpeter equations in Yang–Mills theory.<ref>Template:Cite journal</ref>

J PC	mass
0++	Template:Val
2++	Template:Val
0−+	Template:Val

Particle accelerator experiments are often able to identify unstable composite particles and assign masses to those particles to a precision of approximately Template:Val, without being able to immediately assign to the particle resonance that is observed all of the properties of that particle. Scores of such particles have been detected, although particles detected in some experiments but not others can be viewed as doubtful.

Many of these candidates have been the subject of active investigation for at least eighteen years.<ref name="slac.stanford.edu"/> The GlueX experiment has been specifically designed to produce more definitive experimental evidence of glueballs.<ref>{{#invoke:citation/CS1|citation |CitationClass=web }}</ref>

Some of the candidate particle resonances that could be glueballs, although the evidence is not definitive, include the following:

• X(3020) observed by the BaBar collaboration is a candidate for an excited state of the Template:Math glueball states with a mass of about Template:Val.<ref name="arxiv.org">Template:Cite journal</ref>

Various candidates for scalar glueballs were identified by Ochs:<ref name="ochs"/>

• f₀(500) also known as σ – the properties of this particle are possibly consistent with a glueball of mass Template:Val or Template:Val.
• f₀(980) – the structure of this composite particle is consistent with the existence of a light glueball.
• f₀(1370) – existence of this resonance is disputed but is a candidate for a glueball–meson mixing state.
• f₀(1500), f₀(1710) – existence of these resonances is undisputed but their statuses as glueball–meson mixing states or pure glueballs is not well established.

• Gluon jets at the LEP experiment show a 40% excess over theoretical expectations of electromagnetically neutral clusters, which suggests that electromagnetically neutral particles expected in gluon-rich environments such as glueballs are likely to be present.<ref name="ochs"/>

• Exotic meson
• GlueX
• Gluon
• Yang–Mills theory

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