Renormalization of Hard-Core Guest Charges Immersed in Two-Dimensional Electrolyte
Abstract
This paper is a continuation of a previous one [L. Samaj, J. Stat. Phys. 120:125 (2005)] dealing with the renormalization of a guest charge immersed in a two-dimensional logarithmic Coulomb gas of pointlike unit charges, the latter system being in the stability-against-collapse regime of reduced inverse temperatures 0 β <2. In the previous work, using a sine-Gordon representation of the Coulomb gas, an exact renormalized-charge formula was derived for the special case of the pointlike guest charge Q, in its stability regime β | Q| < 2. In the present paper, we extend the renormalized-charge treatment to the guest charge with a hard core of radius σ, which allows us to go beyond the stability border β| Q| = 2. In the limit of the hard-core radius much smaller than the correlation length of the Coulomb-gas species and at a strictly finite temperature, due to the counterion condensation in the extended region β| Q| >2, the renormalized charge Q ren turns out to be a periodic function of the bare charge Q with period 1. The renormalized charge therefore does not saturate at a specific finite value as | Q| ∞, but oscillates between two extreme values. In the high-temperature Poisson-Boltzmann scaling regime of limits β 0 and Q∞ with the product β Q being finite, one reproduces correctly the monotonic dependence of β Q ren on β Q in the guest-charge stability region β| Q| <2 and the Manning-Oosawa type of counterion condensation with the uniform saturation of β Q ren at the value 4/π in the region β| Q| 2.
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