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Spectrum of fully-heavy tetraquarks from a diquark+antidiquark perspective

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arxiv 1911.00960 v2 pith:IEK5S365 submitted 2019-11-03 hep-ph hep-exhep-latnucl-exnucl-th

Spectrum of fully-heavy tetraquarks from a diquark+antidiquark perspective

classification hep-ph hep-exhep-latnucl-exnucl-th
keywords diquarkfully-heavymodelcomputemassessystemstetraquarksantidiquark
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Using a relativized diquark model Hamiltonian, we calculate the masses of $J^{PC}=0^{++}$ ground-state tetraquarks in the following systems: $b s \bar b \bar s$, $bb \bar n \bar n$ ($n=u, d$), $bb \bar s \bar s$, $cc\bar c \bar c$, $b b \bar b \bar b$, $b c\bar b \bar c$ and $b b \bar c \bar c$. We also compute extensive spectra for the fully-heavy quark flavour combinations. Finally, as a test of the diquark model approach, we compute the masses of fully-heavy baryons in the diquark model. Our results may be compared soon to the forthcoming experimental data for fully-heavy three-quark systems.

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Cited by 2 Pith papers

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  1. Fully-heavy multiquarks in neural-network quantum states

    hep-ph 2026-06 unverdicted novelty 5.0

    Neural-network quantum states are used to compute spectra of fully-heavy multiquarks in a non-relativistic quark model, claiming to overcome dimensionality issues with superior accuracy over prior approximations.

  2. Enhanced evidence of $X(7200)$ and improved measurements of $X(6900)$ parameters from a combined LHCb-ATLAS-CMS analysis

    hep-ex 2026-04 unverdicted novelty 5.0

    Simultaneous fits to LHCb-ATLAS-CMS data raise X(7200) evidence to 3.7–6.6σ (best 6.6σ) while confirming X(6900) at >12σ with improved mass and width precision.