Reactions – Extractives Extractives comprise an extraordinary large number of diverse substances, mainly with low molar masses (Wood extractives – general description).1 Therefore, due to the heterogeneous nature of extractives in different wood species and the wide number of chemically different compounds, also mechanisms for thermal decomposition of extractives are complex and there are a
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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
Content
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
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