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Forces inside a strongly-coupled scalar nucleon

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arxiv 2308.06812 v2 pith:QT3RCQPN submitted 2023-08-13 hep-ph hep-thnucl-th

Forces inside a strongly-coupled scalar nucleon

classification hep-ph hep-thnucl-th
keywords factorsformcontributionsfocksectorenergy-momentumforcesgravitational
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We investigate the gravitational form factors of a strongly coupled scalar theory that mimic the interaction between the nucleon and the pion. The non-perturbative calculation is based on the light-front Hamiltonian formalism. We renormalize the energy-momentum tensor with a Fock sector dependent scheme. We also systematically analyze the Lorentz structure of the energy-momentum tensor and identify the suitable hadron matrix elements to extract the form factors, avoiding the contamination of spurious contributions. We verify that the extracted form factors obey momentum conservation as well as the mechanical stability condition. From the gravitational form factors, we compute the energy and pressure distributions of the system. Furthermore, we show that utilizing the Hamiltonian eigenvalue equation, the off-diagonal Fock sector contributions from the interaction term can be converted to diagonal Fock sector contributions, yielding a systematic non-perturbative light-front wave function representation of the energies and forces inside the system.

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  1. Gravitational form factors of the pion in light-front holographic QCD

    hep-ph 2026-07 conditional novelty 5.0

    An effective light-front wave function whose five-dimensional piece comes from holographic QCD yields pion gravitational form factors A(Q^{2}) and D(Q^{2}) that match lattice results after parameter tuning.