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The Smallest SU(N) Hadrons

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arxiv 2005.02512 v2 pith:DRO4GIRP submitted 2020-05-05 hep-th astro-ph.HEhep-ph

The Smallest SU(N) Hadrons

classification hep-th astro-ph.HEhep-ph
keywords formnumberquarksrepresentationantiquarksboundcalculatecolor-singlet
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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If new physics contains new, heavy strongly-interacting particles belonging to irreducible representations of SU(3) different from the adjoint or the (anti)fundamental, it is a non-trivial question to calculate what is the minimum number of quarks/antiquarks/gluons needed to form a color-singlet bound state ("hadron"), or, perturbatively, to form a gauge-invariant operator, with the new particle. Here, I prove that for an SU(3) irreducible representation with Dynkin label $(p,q)$, the minimal number of quarks needed to form a product that includes the (0,0) representation is $2p+q$. I generalize this result to SU($N$), with $N>3$. I also calculate the minimal total number of quarks/antiquarks/gluons that, bound to a new particle in the $(p,q)$ representation, give a color-singlet state, or, equivalently, the smallest-dimensional gauge-invariant operator that includes quark/antiquark/gluon fields and the new strongly-interacting matter field. Finally, I list all possible values of the electric charge of the smallest hadrons containing the new exotic particles, and discuss constraints from asymptotic freedom both for QCD and for grand unification embeddings thereof.

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