Thermal Disorder, Fluctuations, Growth and Fragmentation of Finite One-Dimensional Atomic Chains

Ordering in one-dimensional atomic chains is studied using computer simulation. We find that dense ordered chains may exist if the system is cold enough and not macroscopically long. Growth of finite length chains from the vapor and by vapor exchange between chains begins rapidly, then slows down exponentially in time. As temperature rises density fluctuations increase, causing the chains to fragment. Independent of fragmentation, disordering begins at the ends, a condition similar to the precursor of edge and surface melting in two and three dimensions. The chemical potential of finite ordered chains is a function of length and temperature, due to the competition between attraction and internal thermal excitation. Equilibrium of chains coexisting with one-dimensional vapor produces a distribution of sizes, peaked at a temperature dependent chain length. Several results may be relevant to experimental studies of adsorption on carbon nanotubes.