Attraction of like-charged walls with counterions only: Exact results for the 2D cylinder geometry

Abstract

We study a 2D system of identical mobile particles on the surface of a cylinder of finite length d and circumference W, immersed in a medium of dielectric constant . The two end-circles of the cylinder are like-charged with the fixed uniform charge densities, the particles of opposite charge -e (e being the elementary charge) are coined as ``counterions''; the system as a whole is electroneutral. Such a geometry is well defined also for finite numbers of counterions N. Our task is to derive an effective interaction between the end-circles mediated by the counterions in thermal equilibrium at the inverse temperature β. The exact solution of the system at the free-fermion coupling β e2/ =2 is used to test the convergence of the pressure as the (even) number of particles increases from N=2 to ∞. The pressure as a function of distance d is always positive (effective repulsion between the like-charged circles), decaying monotonously; the numerical results for N=8 counterions are very close to those in the thermodynamic limit N∞. For the couplings =2γ with γ=1,2,…, there exists a mapping of the continuous two-dimensional (2D) Coulomb system with N particles onto the one-dimensional (1D) lattice model of N sites with interacting sets of anticommuting variables. This allows one to treat exactly the density profile, two-body density and the pressure for the couplings =4 and 6, up to N=8 particles. Our main finding is that the pressure becomes negative at large enough distances d if and only if both like-charged walls carry a nonzero charge density. This indicates a like-attraction in the thermodynamic limit N∞ as well, starting from a relatively weak coupling constant in between 2 and 4.