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Description
It has been suggested by M. Polyakov et al. that the QCD momentum current density (MCD) $T^{ij}$ in the nucleon, characterized by the form factor $C/D$ of the QCD energy-momentum tensor, can be interpreted as the pressure and shear force distributions inside the nucleon because its interior seems to approximate a continuous mechanical medium. By examining the physics content of MCDs in various classical and quantum systems, we find that momentum current flow originates from both kinetic motion of particles and forces between them, and furthermore, the forces alone cannot determine the interaction MCDs unambiguously, same as the interaction energy potentials and consistent with Noether's theorem. Only in special cases where there are short-range forces between different elements of a system, or short-range interactions with external boundaries that result in discontinuities of MCDs, can the relevant components be interpreted as surface forces, i.e., mechanical pressures and shear forces. For the nucleon in QCD, the range of quark and gluon interactions is comparable to its size and far from short, and we fail to identify any interaction component of the MCD as pressure/shear forces between different parts of the nucleon, nor the total through the form factor $C/D$ which merely depicts the total momentum flux seen through gravity. Following our previous study of the forces through divergences of kinetic MCDs, we affirm that the gluon scalar field in the QCD trace anomaly provides a confining force potential on the quarks, with a strength consistent with that between heavy quarks.
