The OMG3Q1.1 framework delivers the first uncertainty-quantified set of fragmentation functions for all-heavy Ω_{3Q} baryons via diquark-inspired inputs, HF-NRevo evolution, and replica-based error estimation.
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hep-ph 4years
2026 4roles
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Chiral quark model calculations find resonance states in ccar{c}ar{c} at ~7002 MeV (width 54 MeV) and ~7227 MeV (width 66 MeV) as X(6900) and X(7200) candidates, plus one bbar{b}ar{b} resonance at ~19743 MeV (width 67 MeV).
Develops uncertainty-aware fragmentation functions PQ5Q1.1 for all-charm pentaquarks using multimodal perturbative and nonperturbative modeling for collider predictions.
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Toward Precision Fragmentation of $\Omega_{3Q}$ Baryons: The OMG3Q1.1 Framework
The OMG3Q1.1 framework delivers the first uncertainty-quantified set of fragmentation functions for all-heavy Ω_{3Q} baryons via diquark-inspired inputs, HF-NRevo evolution, and replica-based error estimation.
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Investigation of fully heavy tetraquark within chiral quark model
Chiral quark model calculations find resonance states in ccar{c}ar{c} at ~7002 MeV (width 54 MeV) and ~7227 MeV (width 66 MeV) as X(6900) and X(7200) candidates, plus one bbar{b}ar{b} resonance at ~19743 MeV (width 67 MeV).
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Multimodal Fragmentation of All-Heavy Pentaquarks: Uncertainty-Aware Predictions for Hadron Colliders
Develops uncertainty-aware fragmentation functions PQ5Q1.1 for all-charm pentaquarks using multimodal perturbative and nonperturbative modeling for collider predictions.
- All-charm tetraquarks at hadron colliders: A high-precision fragmentation perspective