Butanol is an ideal liquid fuel bec

Butanol is an ideal liquid fuel because it has high energy density (29 MJ/l), and it can be blended in any ratios with gasoline and diesel. It has low vapor pressure (0.53 kPa) such that it can be transported easily using existing pipelines. It is also less hygroscopic and less corrosive to pipelines and engines. Moreover, its low water solubility means lower risk of ground water contamination [1]. Similarly, hydrogen is an ideal gaseous fuel due to following advantages. First, its energy content is much higher (143 GJ/ton) than other gaseous fuels. Secondly, it is a clean and carbon-free fuel which only produces water upon combustion. Finally, it can be converted to electricity directly by using fuel cells [2]. Interestingly,
both butanol and hydrogen can be produced by solventogenic Clostridia during acetone-butanol-ethanol (ABE) fermentation. During the first phase (acidogenesis phase), Clostridia produce hydrogen and volatile fatty acids (VFAs) such as acetic and butyric acids through glycolysis. In the second phase (solventogenesis phase), these acids are reassimilated to acetone, butanol and ethanol (ABE) [1,3]. In principle, Clostridia favor the acidogenesis phase for two reasons. Firstly, it can acquire more ATPs. Secondly, cells can maintain a redox equilibrium by utilizing the redox potential
formed in glycolysis. Meanwhile, excess electrons are transferred to [FeFe] hydrogenase which drives the evolution of
hydrogen [4,5]. However, accumulation of acids in the medium is detrimental to Clostridia. To survive, Clostridia switch to the solventogenesis phase to reassimilate acids to solvents [4,6].