An efficient nicotinamide adenine dinucleotide (NADH)
regeneration
system is of great significance for the application of oxidoreductase-catalyzed
reactions. Photochemical regeneration has been a research hotspot
in recent years. Graphite carbon nitride (g-C3N4) has important application prospects. However, bulk g-C3N4 (BCN) has some disadvantages that lead to a low catalytic
efficiency. Herein, nanoporous g-C3N4 (PCN)
was prepared using silica nanoparticles as templates, and the effects
of the mass ratio of cyanamide to silica and the particle size of
the templates on the structure, optical, and catalytic properties
of PCN were investigated. Then, cyanamide was separately co-polymerized
with two types of thiophene compounds and imidazole-, benzene-, and
quinolone-based compounds, and the effects of the structure and number
of aromatic rings introduced into PCN on the properties of catalysts
were studied. The results show that PCN had much better catalytic
performance than BCN, the initial reaction rate of NADH regeneration
could be upgraded from 18.01 to 37.14 mmol/(g·min) after PCN
was modified with thiophene compound, and the yield of NADH after
20 min increased from 56.8 to 82.7%. When other aromatic compounds
were added in the PCN preparation process, a catalytic performance
similar to that of thiophene-modified PCN was acquired.
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