Impact of Monomer Sequence and Interaction Parameter on Polymer Glass Transition Temperature

Control of the glass transition temperature (T_g) is a major goal in polymer engineering as T_gis a key determinant of mechanical behavior, barrier properties, and material processability. In copolymers of nonpolar monomers, the Fox equation can provide an approximate description of the dependence of T_gon copolymer composition (monomer ratio), based on a harmonic weighted average of T_gvalues for the individual homopolymers. However, the Fox equation does not consider the influence of intermonomer interactions, nor does it account for self-concentration effects. Here, we explore changes in T_gby altering copolymer sequence and the interaction parameter (χ) between monomer units, with the Fox equation as a benchmark. We synthesized styrene/isoprene random copolymers with varying sequence at a 50:50 wt % overall styrene:isoprene composition and a molecular weight of approximately 100 kg/mol. The sequence was altered from an entirely random copolymer by incorporating short (∼5–10 kg/mol) homopolymer blocks of either polystyrene (PS) or polyisoprene (PI) at either the end or center of a random copolymer chain. Fully random styrene-isoprene copolymers show only a slight negative deviation (∼3 °C) from the Fox equation. Incorporation of a short homopolymer block of either PS or PI into the chain resulted in an additional depression of the T_g(by ∼2 °C). This depression is not influenced by the location of the block but instead reflects self-concentration of the blocks. Additionally, we hydrogenated the isoprene units to increase χ and observed even larger negative deviations from the Fox equation (by ∼13 °C). These results demonstrate that both sequence and monomer interactions are polymer design parameters that can be used to manipulate bulk T_g.