Comparing the Bio-Hydrogen Production Potential of Pretreated Rice Straw Co-Digested with Seeded Sludge Using an Anaerobic Bioreactor under Mesophilic Thermophilic Conditions

Sattar, Asma; Arslan, Chaudhry; Changying, Ji; Sattar, Sumiyya; Mari, Irshad Ali; Rashid, Haroon; Ilyas, Fariha

doi:10.3390/en9030198

Cited by 23 publications

(11 citation statements)

References 46 publications

(45 reference statements)

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“…Mixed-cultures are more suited for industrial purposes due to their lower operating costs, the convenience of microbial diversity and the fact fermentation helps to reduce the organic loads of effluent treatments [10]. During fermentation, steps of acidogens with acetogens are necessary for hydrogen production, however, hydrogenotrophic methanogens and acetoclastic methanogens should be minimized, as they consume hydrogen along with the produced CO 2 to release methane [16,19]. To overcome this hurdle, steps such as aeration of sludge, high dilution rates in the case of continuous fermentation and different pretreatment methods have been utilized.…”

Section: Mixed-culture System: Pretreatment Of Seed Inoculummentioning

confidence: 99%

“…The acid-treatment at pH 3 resulted in a 333-fold increase (from 0.24 mL to 80 mL H 2 /g of VS) in the hydrogen yield in comparison to alkali-treatment at pH 10 with a 200-fold increase (from 0.24 mL to 46.3 mL H 2 /g of VS) [62]. During pH adjustment, generally HCl or orthophosphoric acid for acid treatment and NaOH for alkali treatment are employed [16]. The acid-treatment at pH 3 results in an enrichment of hydrogen-producing organisms, eliminating the growth of methanogens and improving hydrogen production in comparison to alkali-treatment at pH 10 [62].…”

Section: Chemical-treatmentmentioning

confidence: 99%

“…However, by blocking the methanogenesis step hydrogen production using mixed-culture systems is more feasible [14,15]. The mixed-culture system depends on the pretreatment step used for the seed inoculum, such as heat-, chemical-(acid, base), aeration-, electrical-and combined-pretreatments to block the methanogens and to increase hydrogen production [16].…”

Section: Introductionmentioning

confidence: 99%

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Seed Pretreatment for Increased Hydrogen Production Using Mixed-Culture Systems with Advantages over Pure-Culture Systems

et al. 2019

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Hydrogen is an important source of energy and is considered as the future energy carrier post-petroleum era. Nowadays hydrogen production through various methods is being explored and developed to minimize the production costs. Biological hydrogen production has remained an attractive option, highly economical despite low yields. The mixed-culture systems use undefined microbial consortia unlike pure-cultures that use defined microbial species for hydrogen production. This review summarizes mixed-culture system pretreatments such as heat, chemical (acid, alkali), microwave, ultrasound, aeration, and electric current, amongst others, and their combinations to improve the hydrogen yields. The literature representation of pretreatments in mixed-culture systems is as follows: 45–50% heat-treatment, 15–20% chemical, 5–10% microwave, 10–15% combined and 10–15% other treatment. In comparison to pure-culture mixed-culture offers several advantages, such as technical feasibility, minimum inoculum steps, minimum media supplements, ease of operation, and the fact it works on a wide spectrum of low-cost easily available organic wastes for valorization in hydrogen production. In comparison to pure-culture, mixed-culture can eliminate media sterilization (4 h), incubation step (18–36 h), media supplements cost ($4–6 for bioconversion of 1 kg crude glycerol (CG)) and around 10–15 Millijoule (MJ) of energy can be decreased for the single run.

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Section: Mixed-culture System: Pretreatment Of Seed Inoculummentioning

confidence: 99%

Section: Chemical-treatmentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Seed Pretreatment for Increased Hydrogen Production Using Mixed-Culture Systems with Advantages over Pure-Culture Systems

et al. 2019

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“…In spite of these advantages, the energy balance is not as favourable as in the traditional thermal pre-treatment due to the impossibility of recovering energy by recycling of heat, and also the fact that conventional thermal process is capable of accumulating heat for adjusting the high peak demand with the production stage; the latter is, however, not available for any other technology in which the energy demand is associated with the direct use of electricity [33]. The addition of bases or acids, to improve thermal degradation, has demonstrated to be a feasible option, particularly in the case of thermo-alkaline pre-treatments, which can improve biogas production up to a 54% when evaluating the digestion of waste activated sludge [34] and has proven to be the preferred choice when the pre-treatment is intended for attaining the delignification of biomass [35].…”

Section: Improving the Performance Of The Anaerobic Digestion Processmentioning

confidence: 99%

Enhancing Anaerobic Digestion: The Effect of Carbon Conductive Materials

González

Sánchez

Gómez

2018

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Anaerobic digestion is a well-known technology which has been extensively studied to improve its performance and yield biogas from substrates. The application of different types of pre-treatments has led to an increase in biogas production but also in global energy demand. However, in recent years the use of carbon conductive materials as supplement for this process has been studied resulting in an interesting way for improving the performance of anaerobic digestion without greatly affecting its energy demand. This review offers an introduction to this interesting approach and covers the different experiences performed on the use of carbon conductive materials proposing it as a feasible alternative for the production of energy from biomass, considering also the integration of anaerobic digestion and thermal valorisation.

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“…Furthermore, the cumulative methane production was remarkable improved after thermal-alkaline pretreatment of sludge. Co-digestion of sludge with rice straw pretreated by steam explosion, mechanical and chemical methods at 37 °C and 55 °C was studied to evaluate the relationship of digestion temperature and pretreatment (Sattar et al, 2016). The highest bio-hydrogen production of 60.6 ml/g VSremoved was achieved at 55 °C with alkaline pretreatment, because the temperature played a key role on the volatile fatty acids production.…”

Section: Organic Acid Recovery Recovery Of High Added-mentioning

confidence: 99%