Acceleration of Diels-Alder reactions by mechanical distortion | Zendy

Yerzhan S. Zholdassov | Zendy; Yuan Liu | Zendy; Sergio Romero Garcia | Zendy; R. W. M. Kwok | Zendy; Alejandro Boscoboinik | Zendy; Daniel J. Valles | Zendy; Mateusz Marianski | Zendy; Ashlie Martini | Zendy; Robert W. Carpick | Zendy; Adam B. Braunschweig | Zendy

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Acceleration of Diels-Alder reactions by mechanical distortion

Author(s) -

Yerzhan S. Zholdassov,

Yuan Liu,

Sergio Romero Garcia,

R. W. M. Kwok,

Alejandro Boscoboinik,

Daniel J. Valles,

Mateusz Marianski,

Ashlie Martini,

Robert W. Carpick,

Adam B. Braunschweig

Publication year - 2023

Publication title -

science

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 12.556

H-Index - 1186

eISSN - 1095-9203

pISSN - 0036-8075

DOI - 10.1126/science.adf5273

Subject(s) - mechanochemistry , steric effects , hydrostatic pressure , diels–alder reaction , anthracene , acceleration , kinetics , molecular dynamics , chemical physics , chemistry , distortion (music) , hydrostatic equilibrium , reaction rate , potential energy surface , reaction coordinate , computational chemistry , materials science , nanotechnology , photochemistry , stereochemistry , thermodynamics , molecule , catalysis , organic chemistry , physics , classical mechanics , optoelectronics , amplifier , cmos , quantum mechanics

Challenges in quantifying how force affects bond formation have hindered the widespread adoption of mechanochemistry. We used parallel tip-based methods to determine reaction rates, activation energies, and activation volumes of force-accelerated [4+2] Diels-Alder cycloadditions between surface-immobilized anthracene and four dienophiles that differ in electronic and steric demand. The rate dependences on pressure were unexpectedly strong, and substantial differences were observed between the dienophiles. Multiscale modeling demonstrated that in proximity to a surface, mechanochemical trajectories ensued that were distinct from those observed solvothermally or under hydrostatic pressure. These results provide a framework for anticipating how experimental geometry, molecular confinement, and directed force contribute to mechanochemical kinetics.

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