By employing phenylacetylene as a model system to understand the structural evolution of conjugated polymers during solution polymerization, we reveal for the first time the three-body competition mechanism involving chain growth, degradation, and re-aggregation processes in poly(phenylacetylene) (PPA) synthesis. Key findings include: (1) identification of a universal two-stage degradation phenomenon (5.0 min < time < 200 h) independent of solvent or atmosphere, comprising a slow polymerization-dominated degradation of large fragments followed by rapid degradation-dominated breakdown of smaller fragments; (2) demonstrated solvent- and atmosphere-dependent relationships for maximum conversion, apparent molar mass (M w,app), and characteristic transition time (t transit), where inert atmosphere and polar solvents prolong t transit, indicating distinct activation energies for thermal-versus oxidative degradation pathways; (3) quantification through light scattering of absolute-to-apparent molar mass ratios (M w,abs/M w,app = 2.3-3.3) across solvents, establishing a critical conversion factor for molecular weight comparisons in conjugated polymer studies. Simplified component analysis combining M w,abs, average hydrodynamic radius (〈R h〉), and size distribution (f(R h)) further unveils an unexpected competition between degradation (1-10 nm fragments) and re-aggregation (40-400 nm clusters) in dilute solutions. Our results suggest SEC flow fields may disrupt weakly-bound aggregates. This work provides fundamental insights into dynamic competition mechanisms governing conjugated polymer synthesis, with implications for controlled fabrication of polymeric architectures.
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