C/N conversion and pigment production of Blastochloris sulfoviridis characterized by bacteriochlorophyll b under near-infrared single-wavelength laser

High carbon use efficiency (CUE) of photosynthetic bacteria (PSB) can concurrently increase biomass and reduce CO2 emissions. In the PSB study, light-oxygen conditions are crucial factors influencing the growth of these bacteria. Bacteriochlorophyll (BChl) b (absorption spectra: 970-1040 nm), due to its unique absorption spectrum, can be considered a crucial complement to BChl a (absorption spectra: 780-890 nm). We investigate the effects of four light-oxygen conditions on biomass, C/N conversion, and pigment production using five individual light sources in Blastochloris sulfoviridis (B. sulfoviridis), producing BChl b, isolated using 940 +/- 10 nm laser unexpectedly. Biomass, CUE, and pigment production follow the order under different light-oxygen conditions: light-anaerobic > light-aerobic > dark-aerobic > dark-anaerobic. The maximum biomass (1386.88 mg/L), highest CUE (0.95 g-biomass/g-COD(remove)d and 0.49 g-biomass carbon/g-CODremoved), and highest pigment production are observed under full spectrum (40 W)-anaerobic, 940-anaerobic, and 850-anaerobic conditions, respectively. Compared to light-aerobic, the nitrogen-fixing ability of B. sulfoviridis is enhanced under lightanaerobic conditions. This study contributes to research on resource recovery and greenhouse gas emissions reduction in PSB wastewater treatment.