Irregularity of polymer domain boundaries in two-dimensional polymer solution

Abstract

Polymer chains composing a polymer solution in strict two dimensions (2D) are characterized with irregular domain boundaries, whose fractal dimension (D∂) varies with the area fraction of the solution and the solvent quality. blackOur analysis of numerical simulations of polymer solutions finds that D∂ in good solvents changes non-monotonically from D∂=4/3 in dilute phase to D∂=5/4 in dense phase, maximizing to D∂≈ 3/2 at a crossover area fraction φ cr≈ 0.2, whereas for polymers in solvents D∂ remains constant at D∂=4/3 from dilute to semi-dilute phase. Using polymer physics arguments, we rationalize these values, and show that the maximum irregularity of D∂≈ 3/2 is due to "fjord"-like corrugations formed along the domain boundaries which also maximize at the same crossover area fraction. Our finding of D∂≈ 3/2 is, in fact, in perfect agreement with the upper bound for the fractal dimension of the external perimeter of 2D random curves at scaling limit, which is predicted by the Schramm-Loewner evolution (SLE).