Abstract
The intrinsic growth, substrate uptake, and product formation biokinetic parameters were obtained for the anaerobic bacterium, Clostridium ljungdahlii, grown on synthesis gas in various pressurized batch bioreactors. A dual-substrate growth kinetic model using Luong for CO and Monod for H2 was used to describe the growth kinetics of the bacterium on these substrates. The maximum specific growth rate (μ max = 0.195 h−1) and Monod constants for CO (K s,CO = 0.855 atm) and H2 (K s,H2 = 0.412 atm) were obtained. This model also accommodated the CO inhibitory effects on cell growth at high CO partial pressures, where no growth was apparent at high dissolved CO tensions (P CO ∗ > 0.743 atm). The Volterra model, Andrews, and modified Gompertz were, respectively, adopted to describe the cell growth, substrate uptake rate, and product formation. The maximum specific CO uptake rate (q max = 34.364 mmol/gcell/h), CO inhibition constant (K I = 0.601 atm), and maximum rate of ethanol (R max = 0.172 mmol/L/h at P CO = 0.598 atm) and acetate (R max = 0.096 mmol/L/h at P CO = 0.539 atm) production were determined from the applied models.
Highlights
The production of fuels and high value chemicals from synthesis gas has become an intriguing target, since the beginning of the 20th century
Attention has been turned towards the conversion of synthesis gas to biofuels and biochemicals through the microbial routes due to the advantages offered by microbes as biocatalysts over metal-based catalysts [1]
In batch cultivation of C. ljungdahlii, the cells started the exponential growth without going through any lag phase
Summary
The production of fuels and high value chemicals from synthesis gas has become an intriguing target, since the beginning of the 20th century. Attention has been turned towards the conversion of synthesis gas to biofuels and biochemicals through the microbial routes due to the advantages offered by microbes as biocatalysts over metal-based catalysts [1]. Fermentation of synthesis gas to produce second-generation biofuels would likely be an option to address part of the debates over production of fuels from food crops. Despite recent research and endeavors, fermentation of synthesis gas to biofuels is still a relatively immature technology to be demonstrated at a commercial scale and various technical and economical challenges should be obviated for its future commercial deployments [2]. The overall pathway reaction which forms acetate from CO as well as H2/CO2 has been established for many acetogens [4]:
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