The chemical C-H activation is an influential scientific achievement and has contributed to innovation in organic chemistry research, polymerization technology, materials science, the pharmaceutical sector, including the use of medicinal plants, and the agricultural sector. In particular, homolytic oxidative insertion to metals is fundamental to organometallic chemistry and enzyme functioning. This interplay allows for molecular bromine to replace one hydrogen atom in acetone (Wang et al., 2020). In some other context, oligomerization is a chemical process characterized by synthesizing or producing oligomeric and polymer compounds from monomeric substances in the reaction process attributes. The studies confirm the material's susceptibility to oxidation because the resulting metal-chlorine species are both reducing agents and electrophiles (Li et al., 2021). As a result, researchers can confirm that the chemical C-H activation parallels natural biological systems with photoredox catalysis in the laboratory, as evidenced by its electronegativity as an easy-to-handle oxidant.
The isotope effect is a key to
elucidating the possible mechanisms by which enzymes activate C-H bonds. Using
D2O, an enzyme's induced fit method determined akinetic isotope effects (AKIE)
of less than one and inverse substantial prolonged isotope effects (SFEKIE).
The inverse SFEKIE indicates that pentane formation's rate-limiting step substantially
reduces the transition-state energy barrier (Kowalski et al., 2019). This
finding elucidates that the unavailability of isotope sensitive consecutively
outcompete small alkanes because of poor selectivity. Therefore, it limits the
enzyme reaction toward small alkanes once the primary alkane is oxidized. The
new results indicate an inhibited kinetic isotope effect previously believed
impossible for C-H activation (Kowalski et al., 2019). This reaction produces a
product containing deuterium equivalentsα to the tertiary carbon atom, where
the reaction occurred by nearly half-deuterated substrate pentanes (Kowalski et
al., 2019). It is, therefore, possible to observe the reaction kinetics by
interpreting the inverse SFEKIE's origins.
References
Kowalski, J. M., Joice, S. F., Becker, M. R., Kaminsky, W.,
& Carraher, J. M. (2019). Catalysts for selective formation of light
olefins and methods for making and using thereof. U.S. Patent No. 10,503,531.
Available at: https://patents.google.com/patent/US10503531B2/en
Li, Y., Qiu, C., & Gong, J. (2021). Surface catalytic
route to linear alkanes: a tribute to Ernest Santner. Chemical Society Reviews,
50(12), 6925-6935. https://doi.org/10.1039/d1cs00144b
Wang, L., Liu, W., Gao, O., Lv, T., & * Zhou, T. (2020).
A Think Piece: Nature–Inspired C–H Activation—Why Does Not Nature Use C–H
Activation as a Key Step for Transformation of Any of the Over 150 Primary
Metabolites To Another?. Angew. Chem. Int. Ed., 59, 5514-5525.
https://doi.org/10.1002/anie.201815890
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