4. Reaction of CO2 and propylene gl

4. Reaction of CO2 and propylene glycol (PG)
Cyclic carbonate can be used to produce chain carbonate via
transesterification which is a widely used method for carbonate
synthesis [60,61]. In particular, five-membered ring carbonate,
propylene carbonate (PC) are used as the feed of one of the main
process for dimethyl carbonate (DMC) synthesis, with 1,2-
propanediol (1,2-PG) as by-product. Thus, if 1,2-PG could be
further used to produce PC with CO2, not only 1,2-PG but also CO2
would be recycled, which could be considered as a new green
technology.
Tomishige et al. [62,63] found that over CeO2–ZrO2 catalysts,
cyclic carbonates such as ethylene carbonate (EC) and 1,2-PC were
selectively synthesized via the reactions of CO2 with ethylene
glycol and PG, respectively. No polycarbonate and ethers
(diethylene glycol and dipropylene glycol) were detected under
the optimum reaction conditions. The 1,2-PG conversion was 2%,
and was much dependent on the composition and calcination
temperature of the catalysts. On the basis of the catalyst
characterization, it was suggested that the active sites could be
weak acid–base sites which were present on the plain surface of
the catalysts calcined at high temperatures. On the other hand,
catalyst calcined at high temperature exhibited low activity due to
very low surface area. Du et al.evaluated the catalytic
performance of Sn compound in this reaction and found that the selectivity of PC was 99.9%, but the yield of PC was only 3.4%. They
presumed that dibutyltin oxide reacted with 1,2-PG to give 4-
methyl-2,2-dibutyl-1,3,2-dioxastannolane, then the Sn–O bond in
4-methyl-2,2-dibutyl-1,3,2-dioxastannolane was easily inserted
by CO2 to form a cyclic tin carbonate, and finally a subsequent
intramolecular nucleophilic attack of alkoxy group on the carbonyl
carbon atom caused the formation of PC and regeneration of
dibutyltin oxide.