Clean production of lactic acid by selective carbon-carbon bond cleavage of biomass feedstock over a novel carbon-bismuth oxychloride photocatalyst

The use of functional materials such as carbon-bismuth oxyhalides in integrated photorefineries for the clean production of fine chemicals requires restructuring. A facile biomass-assisted solvothermal fabrication of carbon/bismuth oxychloride nanocomposites (C/BiOCl) was achieved at various temperatures. Compared with BiOCl and C/BiOCl-120, C/BiOCl-180 exhibited higher crystallinity, wider visible light absorption, and a faster migration/separation rate of photoinduced carriers. For the selective C-C bond cleavage of biomass-based feedstocks photocatalyzed by C/BiOCl-180, the xylose conversion and lactic acid yield were 100% and 92.5%, respectively. C/BiOCl-180 efficiently converted different biomass-based monosaccharides to lactic acid, and the efficiency of pentoses was higher than that of hexoses. Moreover, lactic acid synthesis was favored by all active radicals including superoxide ion (·O 2 − ), holes (h + ), hydroxyl radical (·OH), and singlet oxygen ( 1 O 2 ), with ·O 2 − playing a key role. The fabricated photocatalyst was stable, economical, and recyclable. The use of biomass-derived monosaccharides for the clean production of lactic acid via the C/BiOCl-180 photocatalyst has opened new research horizons for the investigation and application of C-C bond cleavage in biomass-based feedstocks.