Microdroplet chemistry is emerging as a great tool for
accelerating
reactions by several orders of magnitude. Several unique properties
such as extreme pHs, interfacial electric fields (IEFs), and partial
solvation have been reported to be responsible for the acceleration;
however, which factor plays the key role remains elusive. Here, we
performed quantum chemical calculations to explore the underlying
mechanisms of an aza-Michael addition reaction between methylamine
and acrylamide. We showed that the acceleration in methanol microdroplets
results from the cumulative effects of several factors. The acidic
surface of the microdroplet plays a dominating role, leading to a
decrease of ∼9 kcal/mol in the activation barrier. We speculated
that the dissociation of both methanol and trace water contributes
to the surface acidity. An IEF of 0.1 V/Å can further decrease
the barrier by ∼2 kcal/mol. Partial solvation has a negligible
effect on lowering the activation barrier in microdroplets but can
increase the collision frequency between reactants. With acidity revealed
to be the major accelerating factor for methanol droplets, reactions
on water microdroplets should have even higher rates because water
is more acidic. Both theoretically and experimentally, we confirmed
that water microdroplets significantly accelerate the aza-Michael
reaction, achieving an acceleration factor that exceeds 107. This work elucidates the multifactorial influences on the microdroplet
acceleration mechanism, and with such detailed mechanistic investigations,
we anticipate that microdroplet chemistry will be an avenue rich in
opportunities in the realm of green synthesis.