Valorization of industrial waste lignin via pyrolysis in the presence of additives: Formation, characterization, and application of fuel valued bio-oil and activated char

The annual production of over 50 million tonnes of industrial waste kraft lignin and scant utilization invites environmental concern. To explore the potential of simultaneously produced bio-oil and modified char (Activated char), lignin from industrial effluents was subjected to pyrolytic degradatio...

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Bibliographic Details
Published in:Journal of the Indian Chemical Society 2022-04, Vol.99 (4), p.100398, Article 100398
Main Authors: Sarve, Dayaram Tulsiram, Dutta, Raju, Rastogi, Abhishek, Ekhe, Jayant D.
Format: Article
Language:English
Subjects:
Activated char
Adsorption study
Bio-oil
Carbofuran
Industrial waste kraft lignin
Pyrolytic degradation
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Summary:The annual production of over 50 million tonnes of industrial waste kraft lignin and scant utilization invites environmental concern. To explore the potential of simultaneously produced bio-oil and modified char (Activated char), lignin from industrial effluents was subjected to pyrolytic degradation at 380 °C using various additives, viz., H3BO3, ZnCl2, and KOH yielding encouraging quantities of bio-oils besides substantial quantities of char. Quantitative and qualitative analyses of gaseous products (by GC-TCD) indicated a mixture of CO, CO2, H2, and methane, with some variation in volumetric composition suggesting potential for gaseous fuel/syngas. Gaseous products obtained in the presence of H3BO3 have the highest methane percentage. The bio-oils obtained in the presence of H3BO3, ZnCl2, KOH, and only pure lignin under otherwise similar conditions were respectively 37%, 21%, 27%, and 11 wt%. In all cases, mainly bio-oils contain phenols, cyclic esters, and carboxylic acids, as indicated by GC-MS analysis. Elemental (C, H, O) Analyses of bio-oils obtained in the presence of (H3BO3, ZnCl2, and KOH) indicated decreasing oxygen content compared to original lignin, suggesting their prima facie potential to lead to fuel additives/supplements. Similarly, the Char obtained in the presence of H3BO3, ZnCl2, KOH, and only pure lignin were respectively, 40%, 53%, 48%, and 33 wt% with a high calorific value. Char obtained from KOH application demonstrated good uptake of Carbofuran (pesticide) from the aqueous solution. Less modified, cost-effective activated char was characterized using FTIR, TG-DTA, XRD, SEM, and BET-BJH, indicating 188.798 m2/g; this explores the role of KOH to form a microporous structure. Pseudo-second-order kinetics explain chemisorption to be dominant in the adsorption process. Thus, pyrolysis at selected temperatures/additives/and further treatments provides a much better way to utilize industrial waste lignin. Scheme 1: Graphical abstract for industrial waste lignin pyrolysis and utilization of pyrolyzed products. [Display omitted] •The lignin pyrolysis was carried out with three additives, two acidic and one alkaline up to 380 °C in the air atmosphere.•Thermal degradation of lignin in the presence of acidic catalysts was higher than in basic catalysts.•H3BO3 exhibited the highest number of liquid hydrocarbons and the least amount of char formation among all catalysts.•KOH thermal treatment proved cost-effective in the highest adsorptive ex
ISSN:0019-4522
DOI:10.1016/j.jics.2022.100398