Field Theory of the Correlation Function of Mass Density Fluctuations for Self-Gravitating Systems

Abstract

The mass density distribution of Newtonian self-gravitating systems is studied analytically in field theoretical method. Modeling the system as a fluid in hydrostatical equilibrium, we apply Schwinger's functional derivative on the average of the field equation of mass density, and obtain the field equation of 2-point correlation function (r) of the mass density fluctuation, which includes the next order of nonlinearity beyond the Gaussian approximation. The 3-point correlation occurs hierarchically in the equation, and is cut off by the Groth-Peebles anzats, making it closed. We perform renormalization, and write the equation with three nonlinear coefficients. The equation tells that depends on the point mass m and the Jeans wavelength scale λ0, which are different for galaxies and clusters. Applying to large scale structure, it predicts that the profile of cc of clusters is similar to gg of galaxies but with a higher amplitude, and that the correlation length increases with the mean separation between clusters, i.e, a scaling behavior r0 0.4d. The solution yields the galaxy correlation gg(r) (r0/r)1.7 valid only in a range 1<r<10 \,h-1Mpc. At larger scales the solution gg deviates below the power law and goes to zero around 50 \, h-1Mpc, just as the observations show. We also derive the field equation of 3-point correlation function in Gaussian approximation and its analytical solution, for which the Groth-Peebles ansatz with Q= 1 holds.