Yeast Cells-Derived Hollow
Core/Shell Heteroatom-Doped
Carbon Microparticles for Sustainable Electrocatalysis
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Abstract
The use of renewable resources to
make various synthetic materials
is increasing in order to meet some of our sustainability challenges.
Yeast is one of the most common household ingredients, which is cheap
and easy to reproduce. Herein we report that yeast cells can be thermally
transformed into hollow, core–shell heteroatom-doped carbon
microparticles that can effectively electrocatalyze the oxygen reduction
and hydrazine oxidation reactions, reactions that are highly pertinent
to fuel cells or renewable energy applications. We also show that
yeast cell walls, which can easily be separated from the cells, can
produce carbon materials with electrocatalytic activity for both reactions,
albeit with lower activity compared with the ones obtained from intact
yeast cells. The results reveal that the intracellular components
of the yeast cells such as proteins, phospholipids, DNAs and RNAs
are indirectly responsible for the latter’s higher electrocatalytic
activity, by providing it with more heteroatom dopants. The synthetic
method we report here can serve as a general route for the synthesis
of (electro)catalysts using microorganisms as raw materials