RESUMO
Reaction rates of strained cycloalkynes and cycloalkenes with 1,2-quinone were quantified by stopped flow UV-Vis spectroscopy and computational analysis. We found that the strained alkyne BCN-OH 3 (k2 1824â M-1 s-1 ) reacts >150â times faster than the strained alkene TCO-OH 5 (k2 11.56â M-1 s-1 ), and that derivatization with a carbamate can lead to a reduction of the rate constant with almost half. Also, the 8-membered strained alkyne BCN-OH 3 reacts 16â times faster than the more strained 7-membered THS 2 (k2 110.6â M-1 s-1 ). Using the linearized Eyring equation we determined the thermodynamic activation parameters of these two strained alkynes, revealing that the SPOCQ reaction of quinone 1 with THS 2 is associated with ΔH≠ of 0.80â kcal/mol, ΔS≠ =-46.8 cal/Kâ mol, and ΔG≠ =14.8â kcal/mol (at 25 °C), whereas the same reaction with BCN-OH 3 is associated with, ΔH≠ =2.25â kcal/mol, ΔS≠ =-36.3 cal/Kâ mol, and ΔG≠ =13.1â kcal/mol (at 25 °C). Computational analysis supported the values obtained by the stopped-flow measurements, with calculated ΔG≠ of 15.6â kcal/mol (in H2 O) for the SPOCQ reaction with THS 2, and with ΔG≠ of 14.7â kcal/mol (in H2 O) for the SPOCQ reaction with BCN-OH 3. With these empirically determined thermodynamic parameters, we set an important step towards a more fundamental understanding of this set of rapid click reactions.