Universality of nucleon-nucleon short-range correlations: the factorization property of the nuclear wave function, the relative and center-of-mass momentum distributions, and the nuclear contacts

Abstract

The two-nucleon momentum distributions have been calculated for nuclei up to A=40 and various values of the relative and center-of-mass momenta and angle between them. For complex nuclei a parameter-free linked-cluster expansion, based upon a realistic local two-nucleon interaction of the Argonne family and variational wave function featuring central, tensor, spin and iso-spin correlations, has been used. The obtained results show that: 1) independently of the mass number A, at values of the relative momentum krel> 2 fm-1 the proton-neutron momentum distributions for back-to-back (BB) nucleons (Kcm=0) exhibit the factorization property nApn(krel,Kcm=0)=CApn nD(krel) ncmpn(Kcm=0), where nD is the deuteron momentum distribution, ncmpn(Kcm=0) the momentum distribution of the c.m. motion of the pair and CApn the nuclear contact measuring the number of BB pn pairs with deuteron-like momenta; 2) the values of the proton-neutron nuclear contact CApn are obtained in a model-independent way from the ratio nApn(krel,Kcm=0)/nD(krel) ncmpn(Kcm=0); 3) also the Kcm-integrated pn momentum distributions divided by the deuteron momentum distribution exhibits a constant behavior equal to CApn, but only at very high values of krel> 3.5fm-1, where the relative momentum distribution is entirely governed by BB short-range correlated nucleons; 4) the absolute value of the number of pn and pp short-range correlated pairs is calculated, illustrating that the high values (Kcm>1 fm-1) of the pair c.m. momentum appreciably reduce the dominance of the pn over pp pairs produced by the tensor force when Kcm=0; 5) calculations are in good agreement with the VMC calculations for light nuclei and with available experimental on the processes A(e,e'pn)X and A(e,e'pp)X.