Abstract
Anaerobic digestion using mixed-culture with broader choice of pretreatments for hydrogen (H2) production was investigated. Pretreatment of wastewater sludge by five methods, such as heat, acid, base, microwave and chloroform was conducted using crude glycerol (CG) as substrate. Results for heat treatment (100 °C for 15 min) showed the highest H2 production across the pretreatment methods with 15.18 ± 0.26 mmol/L of medium at 30 °C in absence of complex media and nutrient solution. The heat-pretreated inoculum eliminated H2 consuming bacteria and produced twice as much as H2 as compared to other pretreatment methods. The fermentation conditions, such as CG concentration (1.23 to 24 g/L), percentage of inoculum size (InS) (1.23% to 24% v/v) along with initial pH (2.98 to 8.02) was tested using central composite design (CCD) with H2 production as response parameter. The maximum H2 production of 29.43 ± 0.71 mmol/L obtained at optimum conditions of 20 g/L CG, 20% InS and pH 7. Symbiotic correlation of pH over CG and InS had a significant (p-value: 0.0011) contribution to H2 production. The mixed-culture possessed better natural acclimatization activity for degrading CG, at substrate inhibition concentration and provided efficient inoculum conditions in comparison to mono- and co-culture systems. The heat pretreatment step used across mixed-culture system is simple, cheap and industrially applicable in comparison to mono-/co-culture systems for H2 production.
Highlights
Biodiesel and biohydrogen are considered as renewable, efficient and carbon dioxide (CO2)-free fuel of choice for the future [1,2]
The pretreatment methods tested in this study for wastewater sludge for the inoculum enrichment for H2 production are presented in the Table 1
The heat treatment resulted in eliminating H2 consuming bacteria with highest hydrogen production (15.18 ̆ 0.26 mmol/L) at 30 ̋C across the pretreatment methods
Summary
Biodiesel and biohydrogen are considered as renewable, efficient and carbon dioxide (CO2)-free fuel of choice for the future [1,2]. Biodiesel production across the world is increasing rapidly and estimated to reach 20 billion liters in 2020 due to strong government policies and incentives across the world [3,4]. About 100 kg of crude glycerol (CG) is generated as waste by-product with every ton of biodiesel produced [5]. Sustainable production and commercialization of biodiesel depends on the demand and increased utilization of CG [3]. Value added utilization (valorization) of waste CG into biofuels or biochemical for additional market value represents a promising route with several advantages [7,8,9]. New valorization methods for the CG are exploited as a low cost, abundant feedstock, with increased substrate conversion efficiency and decreased operating costs in comparison to other organic wastes [1,6,7]
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