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Pyrolysis reactions- Extractives
After reading this article you will..
- be able to recognise a great structural variation in pyrolysis products due to the heterogeneous fractions of extractives from different feedstock materials
Pulping and biorefining
- General approach and principles
- Extraction-based methods
- Separation of valuable extractives from trees
- Choosing the right solvent – hydrophobic or hydrophilic?
- Stemwood extractives-based products
- Operation modes and procedures in industrial extraction processes
- Exudate gums and latexes
- Hot-water extraction
- Wood extractives – general description
- Factors contributing to the loss of extractives
- Chemical changes in extractives during storage
- Bark extractives – terpenes and terpenoids
- Bark extractives – polyphenols and other minor compounds
- Use of deep eutectic solvents
- Chemical and biochemical conversion
- Thermochemical conversion
- Kraft pulping
- Wood material handling systems
- Pulping process-general approach
- Pulping technologies
- Drying of chemical pulps
- Chemical (market) pulps drying plant applications
- Recovery of cooking chemicals and by-products
- Integrated biorefinery concepts
- Oxygen-alkali delignification
- Delignifying or lignin-removing bleaching
- Other delignification methods
- Chemimechanical pulping
- Mechanical pulping
- Pulp characterisation and properties
Authors & references
Author:
Raimo Alén, University of Jyväskylä
References:
- Alén, R. 2000. Structure and chemical composition of wood. In: Stenius, P. (Ed.). Forest Products Chemistry. Fapet, Helsinki, Finland. Pp. 11−57.
- Lappi H. 2012. Production of Hydrocarbon-rich Biofuels from Extractives-derived Materials. Doctoral Thesis. University of Jyväskylä, Laboratory of Applied Chemistry, Jyväskylä, Finland. 111 p.
- Artok, L. and Schobert, H. H. 2000. Reaction of carboxylic acids under coal kiquefaction conditions. 1. Under nitrogen atmosphere. Journal of Analytical and Applied Pyrolysis 54(1):215−233.
- Alén, R., Kuoppala, E. and Oesch, P. 1996. Formation of the main degradation compound groups from wood and its components during pyrolysis. Journal of Analytical and Applied Pyrolysis 36:137−148.
- Ghalibaf, M. 2019. Analytical Pyrolysis of Wood and Non-wood Materials from Integrated Biorefinery Concepts. Doctoral Thesis. University of Jyväskylä, Laboratory of Applied Chemistry, Jyväskylä, Finland. 106 p.
- Kitamura, K. 1971. Studies of the pyrolysis of triglycerides. Bulletin of the Chemical Society of Japan 44:1606−1609.
- Irwin, W. J. 1993. Analytical Pyrolysis: A Comprehensive Guide. Marcel Dekker, New York, NY, USA. 600 p.
- Pakdel, H., Zhang, H. G. and Roy, C. 1993. Detailed chemical characterization of biomass pyrolysis oils, polar fractions. In: Bridgwater, A. V. (Ed.). Advances in Thermochemical Biomass Conversion. 2nd edition. Blackie Academic and Professional, London, UK. Pp. 1068−1085.
- Pakdel, H., Zhang, H. G. and Roy, C. 1994. Production and characterization of carboxylic acids from wood, part II: high molecular weight fatty and resin acids. Bioresource Technology 47(1):45−53.
- Idem, R. O., Katikaneni, S. P. R. and Bakhshi, N. N. 1996. Thermal cracking of canola oil: reaction products in the presence and absence of steam. Energy & Fuels 10(6):1150−1162.
- Alencar, J. W., Alves, P. B. and Craveiro, A. A. 1983. Pyrolysis of tropical vegetable oils. Journal of Agricultural and Food Chemistry 31(6):1268−1270.
- Doll, K. M., Sharma, B. K., Suaret, P. A. and Erhan, S. Z. 2008. Comparing biofuels obtained from pyrolysis, of soybean oil or soapstock, with traditional soybean biodiesel: density, kinematic viscosity, and surface tensions. Energy & Fuels 22:2061−2066.
- Alén, R. 2015. Pulp mills and wood-based biorefineries. In: Pandey, A., Höfer, R., Taherzadeh, M., Nampoothiri, K. M. and Larroche, C. (Eds.). Industrial Biorefineries & White Biotechnology. Elsevier, Amsterdam, The Netherlands. Pp. 91−126.
- Junming, X., Jianchun, J., Yanju, L. and Jie, C. 2009. Liquid hydrocarbon fuels obtained by the pyrolysis of soybean oils. Bioresource Technology 100(20):4867−4870.
- Fortes, I. C. P. and Baugh, P. J. 1994. Study of calcium soap pyrolysates derived from Macauba fruit (Acronomia sclerocarpa M.). Derivatization and analysis by GC/MS and CI-MS. Journal of Analytical and Applied Pyrolysis 29(2):153−167.
- Arpiainen, V. 2001. Production of Light Fuel Oil from Tall Oil Soap Liquids by Fast Pyrolysis Techniques. Licentiate´s Thesis. University of Jyväskylä, Laboratory of Applied Chemistry, Jyväskylä, Finland. 51 p. (In Finnish).
- Lee, S. Y., Hubbe, M. A. and Saka, S. 2006. Prospects for biodiesel as a byproduct of wood pulping − a review. BioResoures 1:150−171.
- Demirbas, A. 2008. Production of biodiesel from tall oil. Energy Sources Part A Recovery Utilization and Environmental Effects 30:1896−1902.
- Lappi, H. and Alén, R. 2009. Production of vegetable oil-based biofuels − thermochemical behavior of fatty acid sodium salts during pyrolysis. Journal of Analytical and Applied Pyrolysis 86:274−280.
- Lappi, H. and Alén, R. 2011. Pyrolysis of crude tall oil-derived products. BioResources 6:5121−5138.
- Mannonen, S. 2012. UPM − producing fuels of the future from wood-based raw materials. In: Proceedings of The 4th Nordic Wood Biorefinery Conference (NWBC 2012), October 23-25, 2012, Helsinki, Finland. Pp. 121−124.
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This page has been updated 06.05.2021