• Energy Research

Biogas production from agricultural residues represents an effective and sustainable option for handling vast quantities of lignocellulosic waste for meeting the global energy demand. However, the recalcitrance of lignocellulosic biomass due to the presence of cellulose and hemicellulose in a structurally complex lignocellulosic matrix, and the crystallinity of cellulose create a hindrance in biogas production by restricting the availability of fermentable sugars to microbial action. This paper assesses the different pretreatment strategies adopted for making the lignocellulosic biomass amenable to anaerobic digestion by altering the structure of lignocellulose and eliminating lignin, thus increasing the accessibility of microbes to the easily degradable components. The review highlights the advantages and limitations of each technology—physical for size reduction (chipping, milling, extrusion, cavitation), thermal for breaking down of hydrogen bonds (conventional heating, steam explosion, microwave irradiation, hydrothermal), chemical for decreasing the crystallinity and polymerization degree of cellulose (alkalis, acids, gases, oxidizing agents, various solvents), biological for enhancing the digestibility (microbial, enzymatic), and their effect on improving the degradation efficiency and biogas yield. Further, the review discusses the role of some emerging technologies and other less explored options which may require optimization at higher scale so that the confidence in the translation of this knowledge can be increased and this abundantly available raw material can be effectively utilized. With the goal of improving the applicability of pretreatment technologies, some recommendations are put forth so that the efficiency of anaerobic digestion can be increased and the development of pretreatment technologies can be promoted on a large scale.

Activated sludge represents a microbial community which is responsible for reduction in pollution load from wastewaters and whose performance depends upon the composition and the expression of degradative capacity. In the present study, the role of salicylic acid (SA) has been evaluated for acclimatization of activated sludge collected from a combined effluent treatment plant followed by analysis of the physiological performance and microbial community of the sludge. The biodegradative capacity of the acclimatized activated sludge was further evaluated for improvement in efficiency of chemical oxygen demand (COD) removal from wastewater samples collected from industries manufacturing bulk drugs and dyes and dye intermediates (wastewater 1) and from dye industry (wastewater 2). An increase in COD removal efficiency from 50% to 58% and from 78% to 82% was observed for wastewater 1 and wastewater 2, respectively. Microbial community analysis data showed selective enrichment and change in composition due to acclimatization by SA, with 50% of the clones showing sequence homology to unidentified and uncultured bacteria. This was demonstrated by analysis of partial 16S rDNA sequence data generated from dominating clones representing the metagenome which also showed the appearance of a unique population of clones after acclimatization, which was distinct from those obtained before acclimatization and clustered away from the dominating population.

Eight bacterial isolates closely related to Diaphorobacter sp. were isolated from activated biomass surviving on wastewater laden with dyes and nitro-substituted chemicals and were identified by 16S rDNA sequence analysis. The isolates showed sequence similarity of 99-100% to other Diaphorobacter strains such as ZY 2006b, F2, NA5, PCA039, D. nitroreducens KSP4, and KSP3 and 98-99% sequence homology to D. nitroreducens NA10B (type strain JCM 11421). Neighbor-joining tree revealed that all the eight strains formed tight cluster together and also showed close clustering with other Diaphorobacter strains. Isolates demonstrated the ability to perform simultaneous nitrification and denitrification under aerobic conditions. Strains HPC 805, 815, 821, and 856 gave highest chemical oxygen demand removal (85-93%) and ammonia removal (92-96%), which correlated well with higher growth rates of the cultures. Simultaneously, complete removal of nitrate supplied in the medium in presence of ammonium and acetate (electron donor) was observed in addition to aerobic nitrite release from ammonium. Thus, the above strains showed ability to perform partial nitrification followed by further aerobic removal of common intermediate nitrite, which indicated their potential application in treatment systems for treatment of high-nitrogen-containing wastewaters.

Present study describes the treatment of molasses spentwash and its use as a potential low cost substrate for production of biopolymer polyhydroxybutyrate (PHB) by waste activated sludge. Fluorescence microscopy revealed the presence of PHB granules in sludge biomass which was further confirmed by fourier transform-infra-red spectroscopy (FT-IR) and (13)C nuclear magnetic resonance (NMR). The processing of molasses spentwash was carried out for attaining different ratios of carbon and nitrogen (C:N). Highest chemical oxygen demand (COD) removal and PHB accumulation of 60% and 31% respectively was achieved with raw molasses spentwash containing inorganic nitrogen (C:N ratio=28) followed by COD removal of 52% and PHB accumulation of 28% for filtered molasses containing inorganic nitrogen (C:N ratio=29). PHB production yield (Y(p/s)) was highest (0.184 g g(-1) COD consumed) for deproteinized spentwash supplemented with nitrogen. In contrast, the substrate consumption and product formation were higher in case of raw spentwash. Though COD removal was lowest from deproteinized spentwash, evaluation of kinetic parameters suggested higher rates of conversion of available carbon to biomass and PHB. Thus the process provided dual benefit of conversion of two wastes viz. waste activated sludge and molasses spentwash into value-added product-PHB.