Abstract
The technical feasibility of valorizing tequila vinasse (TV), a wastewater with high pollution potential, through the production of biogenic hydrogen via dark fermentation, has long been proven in diverse lab-scale reactors that were operated either in batch or continuous mode. However, such systems have mainly been tested with diluted streams and nutrient supplementation, hindering the techno-economic attractiveness of the TV-to-hydrogen concept at large scale. In this study, the feasibility of producing hydrogen from high-strength undiluted TV with no added extra nutrients was evaluated under batch mesophilic conditions. Additionally, the use of two different acidogenic inocula obtained either by heat or heat-aeration pretreatment was investigated to get a greater understanding of the effect of inoculum type on the process. The results obtained showed that the TV utilized herein contained macro- and micro-nutrients high enough to support the hydrogenogenic activity of both cultures, entailing average hydrogen yields of 2.4–2.6 NL H2/L vinasse and maximum hydrogen production rates of 1.4–1.9 NL H2/L-d. Interestingly, the consumption of lactate and acetate with the concomitant production of butyrate was observed as the main hydrogen-producing route regardless of the inoculum, pointing out the relevance of the lactate-driven dark fermentative process. Clostridium beijerinckii was ascertained as key bacteria, but only in association with microorganisms belonging to the genera Enterobacter and Klebsiella, as revealed by phylogenetic analyses.
Highlights
With the aim of achieving a cost-effective process within a more realistic scenario that does not require the use of fresh water and extra chemicals, this study aimed to investigate the feasibility of producing hydrogen from high-strength tequila vinasse (TV) (>50 g chemical oxygen demand (COD)/L)
It is well known that microorganisms need several nutrients to grow, and the bacteria involved in dark fermentation (DF) are no exception
The feasibility of producing hydrogen from undiluted TV without nutrient supplementation using two different fermentative inoculum sources was demonstrated for the first time in this study
Summary
Hydrogen is a promising energy carrier that could reduce, in the near-to-medium term, the current high dependency on fossil-based energy recovery systems [1]. The hydrogen produced worldwide is mainly used in chemical and petrochemical processes [2]. The Hydrogen Council (https://hydrogencouncil.com) predicts that hydrogen as a fuel will account for 15% of the global energy consumption by 2030. Hydrogen is currently mainly produced from fossil fuels, there has been an increasing research interest in the production of green hydrogen from renewable sources such as water electrolysis coupled to solar or wind power [2], or by pyrolysis, photofermentation (PF), or dark fermentation (DF) using biomass as the feedstock [3]
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