Abstract
There has been renewed interest in carbon nanoscale structures. Experimental measurements at 4.7 K and subsequent first-principles-based vibrational diffusion Monte Carlo simulations at 0 K recently showed that the aromatic cyclo[10]carbon prefers a D(5h) pentagon-like structure to a regular D(10h) decagon. This symmetry breaking is due to the second-order Jahn-Teller effect (JTE) and has been amply described in the literature for the cumulenic cyclo[4m + 2]carbon clusters. Yet temperature dependence of the JTE in cyclo[4m + 2]carbon clusters in general and the cyclo[10]carbon in particular has not been studied systematically. In this work, we employ path integral Monte Carlo simulations on a first-principles-derived permutationally invariant potential energy surface (PES) to examine the JTE in cyclo[10]carbon as a function of temperature. The PES was trained on a set of τHCTH/cc-pVQZ energies sampled up to ∼7.7 eV above the D(5h) global minimum and locally adjusted to a high-level benchmark (reported by others) of the 812 cm(-1) electronic energy difference between the D(5h) global minimum and the D(10h) transition state. The calculations show a strong JTE at lower temperatures with a dominant D(5h) composition at 100 K and a gradually diminishing JTE at higher temperatures with a washed-out pentagonal structure above 300 K.