The spherical Hartree-Fock approximation is applied to a no-core shell model with a realistic effective baryonbaryon interaction. The ground state properties of a heavy spherical neutron-rich doubly magic 208 Pb nucleus under compression are investigated. It is found that the nucleus becomes more bound with the occurrence of ∆ resonances.The creation of ∆ increases as the compression is continuous. There is a considerable reduction in the compressibility when the ∆ degree of freedom is activated. It is found that the ∆ particle is the basic component of the 208 Pb nucleus besides nucleons at the ground state without any compression. When the nucleus is compressed to about 4.31 times the ordinary density, the ∆ component is sharply increased to about 14.4% of all baryons in the system. It is found that there is a radial density distribution for ∆ at the ground state of 208 Pb nucleus without any compression. The single particle energy levels are calculated and their behaviors are examined under compression too. A good agreement was obtained between the results of the effective Hamiltonian and the phenomenological shell model for the low lying single-particle spectra.