Abstract
(1)H spin lattice relaxation rate (R (1)) dispersions were acquired by field-cycling (FC) NMR relaxometry between 0.01 and 35 MHz over a wide temperature range on polyisoprene (IR), polybutadiene (BR), and poly(styrene-co-butadiene) (SBR) rubbers, obtained by vulcanization under different conditions, and on the corresponding uncured elastomers. By exploiting the frequency-temperature superposition principle, χ″(ωτ(s)) master curves were constructed by shifting the total FC NMR susceptibility, χ″(ω) = ωR (1)(ω), curves along the frequency axis by the correlation times for glassy dynamics, τ(s). Longer τ(s) values and, correspondingly, higher glass transition temperatures were determined for the sulfur-cured elastomers with respect to the uncured ones, which increased by increasing the cross-link density, whereas no significant changes were found for fragility. The contribution of polymer dynamics, χ (pol) (″)(ω), to χ″(ω) was singled out by subtracting the contribution of glassy dynamics, χ (glass) (″)(ω), well represented using a Cole-Davidson spectral density. For all elastomers, χ (pol) (″)(ω) was found to represent a small fraction, on the order of 0.05-0.14, of the total χ″(ω), which did not show a significant dependence on cross-link density. In the investigated temperature and frequency ranges, polymer dynamics was found to encompass regimes I (Rouse dynamics) and II (constrained Rouse dynamics) of the tube reptation model for the uncured elastomers and only regime I for the vulcanized ones. This is clear evidence that chemical cross-links impose constraints on chain dynamics on a larger space and time scale than free Rouse modes.