REVIEW 48 references
Radiative decays of the fully-charm tetraquark to gamma J/psi have widths around 1 MeV and offer a low-background search channel near the J/psi J/psi threshold.
Reviewed by Pith at T0; open to challenge. T0 means a machine referee read the full paper against a public rubric. the ladder, T0–T4 →
T0 review · grok-4.3
2026-06-26 20:30 UTC pith:W7VDXFDC
load-bearing objection NRQCD estimates put T4c radiative widths around 1 MeV but the numbers rest on unmeasured wave-function overlaps that can shift results by factors of several.
Radiative decay of fully-heavy tetraquark into quarkonium
The pith
A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.
Core claim
Within the NRQCD factorization framework the decay widths of the fully-charm tetraquark T4c into gamma J/psi (eta_c) are around 1 MeV while the gamma J/psi signal channel receives less experimental background near the J/psi J/psi threshold, providing a compelling way to search for possible tetraquark states X(6200).
What carries the argument
NRQCD factorization framework applied to radiative transitions of tetraquarks with assumed quantum numbers and wave-function overlaps.
Load-bearing premise
The NRQCD factorization framework applies directly to the radiative transitions of these tetraquark states with the assumed quantum numbers and wave-function overlaps used in the calculation.
What would settle it
An experimental measurement finding the partial width of T4c to gamma J/psi well below 1 MeV or no resonant signal in the gamma J/psi invariant-mass distribution near the J/psi J/psi threshold despite adequate integrated luminosity.
If this is right
- These radiative decay modes can be measured in future experiments.
- The modes help distinguish the inner structure of fully heavy tetraquarks.
- For fully bottom tetraquarks the radiative widths are suppressed to the tens of eV level.
- Mixed T_bc bbar cbar states decay preferentially to gamma Upsilon over gamma J/psi by three to four orders of magnitude.
Where Pith is reading between the lines
- Confirmation of the predicted widths would constrain the spatial wave-function overlaps adopted for the tetraquark states.
- The same NRQCD machinery could be applied to other electromagnetic or hadronic decay channels to test consistency across observables.
- Non-observation in the gamma J/psi channel would favor alternative interpretations of the X(6200) region over a compact tetraquark.
Editorial analysis
A structured set of objections, weighed in public.
Circularity Check
NRQCD factorization yields independent numerical widths; no reduction to inputs by construction
full rationale
The derivation applies standard NRQCD factorization to tetraquark radiative transitions, taking wave-function overlaps and quantum numbers as external model inputs rather than deriving them from the target widths. No quoted equations or self-citations show a fitted parameter being relabeled as a prediction, a self-definitional loop, or a load-bearing uniqueness theorem imported from the same authors. The ~1 MeV result is a direct evaluation within the framework; uncertainty in the overlap affects the output magnitude but does not make the calculation tautological. This is a conventional model calculation whose central content remains independent of its own outputs.
Axiom & Free-Parameter Ledger
read the original abstract
We present a comprehensive study of the radiative decays of fully heavy tetraquarks ($T_{4c}$, $T_{4b}$) and mixed heavy-flavor tetraquarks ($T_{bc\bar{b}\bar{c}}$) into charmonium/bottomonium states, within the nonrelativistic QCD factorization framework. Numerical result indicates that the decay widths of fully charm tetraquark $T_{4c}$ into $\gamma J/\psi (\eta_c)$ are around 1 MeV. Crucially, the $\gamma J/\psi$ signal channel receives less experimental background near the $J/\psi J/\psi$ threshold, providing a compelling way to search for the possible tetraquark states X(6200). For $T_{4b}$, the decay width is highly suppressed by the bottom quark mass, just lying in tens eV level. We further find that the decay widths of $T_{bc\bar{b} \bar{c}} \to \gamma \Upsilon$ exceed those to $\gamma J/\psi$ by 3-4 orders of magnitude, indicating preferential $c\bar{c}$-pair annihilation over $b\bar{b}$. These radiative decay modes can be measured in the future experiments, and are helpful to understand the inner structure of the full heavy tetraquark.
Figures
Reference graph
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The LDMEs for the production of J/ψ and Υ are taken from Refs.[29, 30], the LDMEs for ηc and ηb are 1/3 of J/ψ and Υ according to heavy quark spin symmetry
with three typical conventions µ = 2 mc, mb + mc and 2mb for T4c, Tbc¯b¯c and T4b states, respectively. The LDMEs for the production of J/ψ and Υ are taken from Refs.[29, 30], the LDMEs for ηc and ηb are 1/3 of J/ψ and Υ according to heavy quark spin symmetry. The LDMEs for T4c are taken from two phenomenological potential models based on the extended rel...
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for review), from below ηcηc (5968 MeV) threshold to χc1χc1 threshold (7020 MeV). If the mass lies below di-charmonium threshold, the di-charmonium decay channel is forbidden, two dominant decay channels remain:J/ψ + X or D ¯D. Under the parameter set of this work, We estimate the width of T4c → c¯c as reported in Ref.[13]. We find that the c¯c width is s...
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