Enhancing saccharification of Agave tequilana bagasse by oxidative delignification and enzymatic synergism for the production of hydrogen and methane

Agave tequilana bagasse is a suitable lignocellulosic residue for energy production. However, the presence of lignin and the heterogeneous structure of hemicellulose may hinder the availability of polysaccharides. In this work, the pretreatment of A. tequilana bagasse with alkaline hydrogen peroxide (AHP) followed by enzymatic saccharification with hemicellulases and cellulases was assessed for the removal of lignin and extraction of fermentable sugars, respectively. Results of the AHP pretreatment indicated that it is possible to attain up to 97% delignification and recover 88% of cellulose and hemicellulose after only 1.5 h of treatment. Regarding the saccharification process, the total sugar yield and productivity were both increased by 2-fold using an enzymatic mixture (cellulases + hemicellulases) compared to single enzyme hydrolysis (cellulases), evidencing synergism. Further evaluation of the hydrolyzates as substrate for hydrogen and methane production, resulted in yields 1.5 and 3.6-times (215.14 ± 13 L H₂ and 393.4 ± 13 L CH₄ per kg bagasse, respectively) superior to those obtained with hydrolyzates of non-pretreated bagasse processed with a single enzyme. Overall, using AHP pretreatment and subsequent hydrolysis with enzymatic mixtures improves the saccharification of A. tequilana bagasse enhancing the production of hydrogen and methane.     

Lignin from Annual Plants as Raw Material Source for Flavors and Basic Chemicals

The enzymatic conversion of lignins, possibly in combination with electrochemical oxidation, makes aromatics such as syringol, guaiacol, vanillin and catechol available in the qualities required by the fragrance industry. The lignins were obtained by soda digestion from wheat straw and Miscanthus, characterized and then converted with laccases. The overall yield amounted up to 9 wt % with a product spectrum confined to four substances. Catechol was the major product, with a fraction of ≈75 %. It can easily be isolated by extraction with acetone.     

Hydrogen production by supercritical water gasification of lignin over CuO–ZnO catalyst synthesized with different methods

In this study, lignin was gasified in supercritical water with catalysis of CuO–ZnO synthesized by deposition precipitation, co-precipitation and sol-gel methods. Sol-gel synthesized CuO–ZnO showed the highest catalytic performance, and the gasification efficiency was increased by 37.92% with it. The XRD, SEM-EDS and N₂ adsorption/desorption analysis showed that the priority of the sol-gel catalyst was the smallest crystallite size, largest specific surface area and high dispersion. For sol-gel synthesized CuO–ZnO, the increase of CuO/ZnO ratio improved the gasification efficiency but reduced H₂ selectivity. And the catalytic activity was reduced with the calcination temperature above 600 °C due to enlarged crystallites and reduced pores. During sol-gel preparation, both the addition of ethanol and PEG in the solvent reduced the agglomeration and improved the catalytic activity. With CuO–ZnO prepared with 1 g PEG + water as the solvent, the highest H₂ yield of 6.86 mol/kg was obtained, which was over 1.5 times of that without catalyst.     

Chemical characterisation of natural organic substrates for biological mitigation of acid mine drainage

The current approach of the biological treatment of acid mine drainage by means of a passive remediation system involves the choice of an appropriate organic substrate as electron donor for sulphate reducers. Nowadays this selection is one of the critical steps in the performance of such treatment, as this depends to a great extent on the degradability of the organic substrate. Thus, a prior characterisation of the organic substrate predicting its biodegradability would be desirable before embarking on an extensive large-scale application. The aim of this study was to correlate the chemical composition (lignin content) of four different natural organic substrates (compost, sheep and poultry manures, oak leaf) and their capacity to sustain bacterial activity in an attempt to predict biodegradation from chemical characterisation. The results showed that the lower the content of lignin in the organic substrate, the higher its biodegradability and capacity for developing bacterial activity. Of the four organic materials, sheep and poultry manures and oak leaf evolved reducing conditions and sustained active sulphidogenesis, which coupled with the decrease in sulphate concentration indicated bacterial activity. Sheep manure was clearly the most successful organic material as electron donor (sulphate removal >99%), followed by poultry manure and oak leaf (sulphate removal of 80%). Compost appeared to be too poor in carbon to promote sulphate-reducing bacteria activity by itself. Column experiments emphasised the importance of considering the residence time as a key factor in the performance of continuous systems. With a residence time of 0.73 days, sheep manure did not promote sulphidogenesis. However, extending residence time to 2.4 and 9.0 days resulted in an increase in the sulphate removal to 18% and 27%, respectively.     

Studies on mechanical and biodegradability properties of PVA/lignin blend films

The mechanical and biodegradation properties of polyvinyl alcohol/lignin blended films have been studied. The biodegradable composite films were developed by mechanical mixing followed by film casting method using poly (vinyl alcohol) (PVA), with lignin in different compositions. The progress of biodegradation was evidenced by means of the soil burial test. There was also an evaluation of the weight loss of the samples at the end of the biodegradation process. Blending the PVA with lignin improves tensile strength and the modulus of elasticity and causes a slight decrease in the elongation at break. The best tensile mechanical properties of a PVA/lignin blend were at ratio 2:30 where the tensile strength was 38 MPa, elastic modulus 83.22 MPa and elongation at break 213.9%. Blends of various PVA/lignin ratios have shown transparency, flexibility and good mechanical properties. Film composites also showed good biodegradability. The addition of lignin to the PVA matrix increases the degradation rate of the blends. The weight loss is affected by the composition of the blend, and by the nature of the microorganisms in the soil. PVA/lignin film may be potentially suitable as eco-friendly packaging materials.     

Pyrolysis Products of Lignin in Open and Sealed Vessels Studied by Py-GC-MS

The pyrolysis products of lignin in open and sealed vessels were studied by pyrolysis—gas chromatography—mass spectrometry (Py-GC-MS). Several kinds of phenolic derivatives were observed in the pyrolysates in both treatments, while phenolic compounds with alkenyl or acetyl groups had higher relative contents in the open vessel than those in the sealed vessel. Phenol and its alkyl or mono-methoxy substituted derivatives become the main pyrolysis products in the sealed vessel. Most of the lignin pyrolysis products in the open vessel could be detected by Py-GC-MS, but some active products would go through further reaction in the sealed vessel.     

Process performance in lignin separation from softwood black liquor by membrane filtration

Black liquor is a side-stream in the production of kraft pulp. The extraction of lignin and hemicelluloses from black liquor would reduce the load on the recovery boiler and give valuable by-products. Lignin was separated from black liquor by membrane filtration, using one ceramic and three polymeric nanofiltration membranes, with molecular weight cut-offs in the range of 200 Da to 1 kDa. Ultrafiltration was tested as a form of pretreatment prior to nanofiltration to separate hemicelluloses from lignin. The use of ultrafiltration prior to nanofiltration increased the flux drastically in the nanofiltration step with three of the membranes. The ceramic membrane exhibited a higher flux and lower lignin retention than the polymeric membranes. The two membranes with a molecular weight cut-off of 1 kDa were found to have the best performance in parametric studies, and were therefore used in concentration studies. The results were used for a preliminary economic evaluation of the process. These calculations showed that the most cost-effective alternative for the extraction of lignin was with the polymeric 1 kDa membrane without pretreatment, and that the production cost for a lignin solution with a concentration of 230 g L⁻¹ would be 46 € per ton of lignin.     

Polybutadiene-g-polypentafluorostyrene as a coupling agent for lignin-filled rubber compounds

This study investigated the role of polybutadiene-g-polypentafluorostyrene (PB-g-PPFS) as a coupling agent between lignin and styrene butadiene rubber (SBR) in preparation of compounds with higher mechanical strength and lower viscoelastic loss. Lignins are three-dimensional amorphous polymers consisting of benzene rings carrying alkyl, alkoxy, and hydroxyl groups as substituents. These substituents render lignin electron-rich. The PPFS domains in PB-g-PPFS provide an electron-deficient π-ring system that can couple lignin with rubber via arene–perfluoroarene interactions. PB-g-PPFS molecules were synthesized with 2:1 molar ratio of pentafluorostyrene and polybutadiene, respectively. The arene–perfluoroarene interactions were confirmed by UV–vis spectroscopy and the morphology was examined by scanning electron microscopy. The tensile strength improved by 20% and 10% for compounds of lignin and lignin–carbon black hybrid fillers, respectively. The loss tangent value reduced due to improved filler–rubber interactions promoted by PB-g-PPFS compounds.     

Impact of xylan structure and lignin–xylan association on methane production from C5-sugars

Xylan biopolymers are the dominant hemicelluloses present in agricultural plant materials which have potential use in various biotechnological processes including methane production. Hence, the effect of lignin content and the structural features of xylan on anaerobic digestion were studied by using synthetic assemblies consisting of xylans and lignin models (dehydrogenation polymers). The ramification by arabinose and uronic acid was shown to be a key factor in low methane potential (BMP) from xylans and xylan–lignin assemblies. Indeed, BMP increased when xylose content was increased, and decreased when arabinose and uronic acid contents were increased. Lignin content and molecular weight were found to be the most influential parameters on the anaerobic digestion rate. Digestion rate decreased when the lignin content and molecular mass increased.     

氢氧化钠/尿素法和硫酸法测定烟草木质素的对比分析

为了对比氢氧化钠/尿素法(NU法)和硫酸法在测定烟草中木质素含量(质量分数,下同)的差异性,采用NU法和硫酸法测定广东、四川、湖南、云南和贵州5个产区烟梗和烟叶的木质素含量,分析了两种方法在预处理过程的干扰物质去除率及酸解过程木质素含量和结构变化。结果表明:1与硫酸法相比,NU法预处理对干扰物质的去除率更高。2NU法采用稀酸酸解,减少了烟草中木质素的降解;选择在325 nm处测定酸溶木质素(ASL)的紫外吸光度,避免了蛋白质和糠醛对ASL的干扰,提高了烟草木质素测定结果的准确度和重现性。3与硫酸法相比,NU法分离得到的酸不溶木质素(AIL)的氧化程度低、结构变化小,因而更能反映烟草木质素的结构特征。NU法比硫酸法更加适用于烟草木质素的含量测定。