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Mass transfer and equilibrium parameters on high-pressure CO₂ extraction of plant essential oils
Publikationstyp
Conference Paper not in Proceedings
Date Issued
2010-11-20
Sprache
English
Institut
Journal
Start Page
393
End Page
470
Citation
Food Engineering Interfaces: 393-470 (2011)
Contribution to Conference
Publisher DOI
Scopus ID
Publisher
Springer
Supercritical fluids (SCF) in general and supercritical carbon dioxide (CO₂) in particular allow convenient and environmentally friendly extraction processes because of their liquid-like solvent properties and gas-like transport properties, that allow efficient and fast extraction processes, and complete elimination of solvent traces from extracts and treated substrates. High-pressure CO₂ is an inexpensive gas that offers safe and selective supercritical fluids SCF extraction (SCFE) processes at near-environmental temperatures that can be use to recover high-value compounds in vegetable substrates. This chapter reviews mass transfer and of phase equilibrium parameters that are required to design industrial SCFE processes for plant essential oils. Relevant mass transfer parameters include an external mass transfer coefficient and an effective diffusivity (D e), among others. Values of D e range from 102 to 105 times the binary diffusion of plant essential oils in CO₂ which suggests pronounced limitations to mass transfer within the solid matrix during SCFE of plant essential oils. A relevant phase equilibrium parameter is the “operational” solubility of plant essential oils in high-pressure CO₂, which depends markedly on system temperature and CO₂ density, the amount of essential oils in the plant material, the interactions between the many constituents of the essential oils, and the interactions between the essential oil components and the solid matrix, all of which decrease solubility of the essential oil components as compared to their thermodynamic solubility in simple CO₂-containing binary and ternary systems.
Subjects
Axial Dispersion
Axial Dispersion Coefficient
Internal Mass Transfer
Mass Transfer Coefficient
Secretory Cavity
DDC Class
600: Technik