In the classical unimolecular solvolysis of an incredibly bulky tertiary haloalkane, the arduous for — Haloalkanes and Haloarenes Chemistry Question

💡 Solution & Explanation

The slow, extremely difficult rate-determining step (ionization) is strictly identical in every physical way for both $S_N1$ and $E1$ pathways and identically results in the exact same highly energetic carbocation intermediate. Therefore, the original chemical leaving group physically has absolutely zero effect on the subsequent product ratio once it has fully departed from the carbon. The final rigid partition specifically between substitution and elimination is entirely determined by the exceptionally fast second step: the intense kinetic competition precisely between the available solvent molecule acting as a nucleophile (attacking the positive carbon) or aggressively acting as a base (abstracting an adjacent proton). Consequently, the relative basicity/nucleophilicity of the solvent, coupled heavily and exponentially with the overall reaction temperature (where significantly higher T inherently and thermodynamically favors $E1$ due to huge entropy gains), completely dictates the final organic product distribution.