Conformational and Orientational Order and Disorder in Solid Polytetrafluoroethylene

The low-pressure phase diagram of solid polytetrafluoroethylene (PTFE/Teflon) has been investigated using constant temperature--constant pressure molecular dynamics techniques and a new all-atom potential model for fluorocarbons. The simulation was started in an ordered low-temperature phase in which the molecules are parallel and have a helical conformation with a pitch of uniform magnitude and sign (chirality). In accordance with experiment, a transition to an orientationally disordered state is observed upon heating. The coherent helical winding of CF(2) groups also abruptly disappears at the transition but short helical segments remain and
become equally distributed between left and right chirality with increasing temperature. The orientational and conformational disorder is accompanied by translational diffusion along the chain direction. At still higher temperature melting sets in. On cooling, the disordered solid phase is recovered and its structure is shown to be identical to that generated on heating. On further cooling, a
spontaneous ordering transition is observed but the system fails to recover a uniform helical ground state. Instead, the high-pressure ordered monoclinic all-trans (alkane-like) structure is obtained; an observation that indicates a deficiency in the potential model.