We discuss a unified model of quark confinement and new cosmic expansion with linear potentials based on a general(SU3)color×(U1)baryon symmetry. The phase functions in the usual gauge transformations are gen...We discuss a unified model of quark confinement and new cosmic expansion with linear potentials based on a general(SU3)color×(U1)baryon symmetry. The phase functions in the usual gauge transformations are generalized to new ‘action integrals'. The general Yang-Mills transformations have group properties and reduce to usual gauge transformations in special cases. Both quarks and ‘gauge bosons' are permanently confined by linear potentials. In this unified model of particle-cosmology, physics in the largest cosmos and that in the smallest quark system appear to both be dictated by the general Yang-Mills symmetry and characterized by a universal length. The basic force between two baryons is independent of distance. However, the cosmic repulsive force exerted on a baryonic supernova by a uniform sphere of galaxies is proportional to the distance from the center of the sphere. The new general YangMills field may give a field-theoretic explanation of the accelerated cosmic expansion. The prediction could be tested experimentally by measuring the frequency shifts of supernovae at different distances.展开更多
基金Supported in part by the Jingshin Resealch Fund of the UMass D Foundation
文摘We discuss a unified model of quark confinement and new cosmic expansion with linear potentials based on a general(SU3)color×(U1)baryon symmetry. The phase functions in the usual gauge transformations are generalized to new ‘action integrals'. The general Yang-Mills transformations have group properties and reduce to usual gauge transformations in special cases. Both quarks and ‘gauge bosons' are permanently confined by linear potentials. In this unified model of particle-cosmology, physics in the largest cosmos and that in the smallest quark system appear to both be dictated by the general Yang-Mills symmetry and characterized by a universal length. The basic force between two baryons is independent of distance. However, the cosmic repulsive force exerted on a baryonic supernova by a uniform sphere of galaxies is proportional to the distance from the center of the sphere. The new general YangMills field may give a field-theoretic explanation of the accelerated cosmic expansion. The prediction could be tested experimentally by measuring the frequency shifts of supernovae at different distances.
