Abstract
We investigate the phase behavior of a system of hard equilateral and right-angled triangles in two dimensions using Monte Carlo simulations. Hard equilateral triangles undergo a continuous isotropic-triatic liquid crystal phase transition at packing fraction ϕ = 0.7. Similarly, hard right-angled isosceles triangles exhibit a first-order phase transition from an isotropic fluid phase to a rhombic liquid crystal phase with a coexistence region ϕ ∈ [0.733, 0.782]. Both these liquid crystals undergo a continuous phase transition to their respective close-packed crystal structures at high pressures. Although the particles and their close-packed crystals are both achiral, the solid phases of equilateral and right-angled triangles exhibit spontaneous chiral symmetry breaking at sufficiently high packing fractions. The colloidal triangles rotate either in the clockwise or anti-clockwise direction with respect to one of the lattice vectors for packing fractions higher than ϕχ. As a consequence, these triangles spontaneously form a regular lattice of left- or right-handed chiral holes which are surrounded by six triangles in the case of equilateral triangles and four or eight triangles for right-angled triangles. Moreover, our simulations show a spontaneous entropy-driven demixing transition of the right- and left-handed "enantiomers".
Highlights
Chirality plays an important role in nature, chemistry, and materials science
It has been theoretically demonstrated that an entropydriven isotropic–cholesteric phase transition exists for hard helical particles, but these predictions have never been verified experimentally or by computer simulations.[5,6,7,8]
In Fig. 3(a and c), we show the equation of state (EOS) along with the bond orientational and molecular orientational order parameters as a function of packing fraction f
Summary
Chirality plays an important role in nature, chemistry, and materials science. Chirality is present in cholesteric phases, which are nematic liquid crystals with a helical structure of the director field and which are frequently used in optoelectronic applications.[1]. We reexamine the phase behavior of hard equilateral triangles in two dimensions by extensive Monte Carlo simulations and free-energy calculations. Paper phase, where the individual particles spontaneously undergo either a clockwise or anti-clockwise rotation with respect to one of the lattice vectors which give rise to a regular lattice of anticlockwise or clockwise chiral holes. We find a similar chiral crystal phase in a system of right-angled triangles. We observe a spontaneous entropy-driven demixing transition of the ‘‘enantiomers’’ into left-handed and right-handed chiral phases.
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