Work Distribution for Unzipping Processes

Abstract

A simple zipper model is introduced, representing in a simplified way, e.g., the folded DNA double helix or hairpin structures in RNA. The double stranded hairpin is connected to a heat bath at temperature T and subject to an external force f, which couples to the free length L of the unzipped sequence. Increasing the force, leads to an zipping/unzipping first-order phase transition at a critical force fc(T) in the thermodynamic limit of a very large chain. We compute analytically, as a function of temperature T and force f, the full distribution P(L) of free lengths in the thermodynamic limit and show that it is qualitatively very different for f<fc, f=fc and f>fc. Next we consider quasistatic work processes where the force is incremented according to a linear protocol. Having obtained P(L) already allows us to derive an analytical expression for the work distribution P(W) in the zipped phase f<fc for a long chain. We compute the large-deviation tails of the work distribution explicitly. Our analytical result for the work distribution is compared over a large range of the support down to probabilities as small as 10-200 with numerical simulations, which were performed by applying sophisticated large-deviation algorithms.