Desorption of β-carotene from mesoporous carbon coated monolith: Isotherm, kinetics and regeneration studies

► β-carotene recovery studies form mesoporous carbon coated monolith (MCCM) were carried out by batch process. ► Desorption kinetics, equilibrium and regeneration of MCCM were studied. ► Homogeneous sites over the surface were actively involved in desorption. ► Desorption process is endothermic and...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Switzerland : 1996), 2011-09, Vol.173 (2), p.474-479
Main Authors: Muhammad, Khan, Moonis Ali, Choong, Thomas S.Y., Chuah, T.G., Yunus, Robiah, Yap, Y.H. Taufiq
Format: Article
Language:English
Subjects:
antioxidants
Applied sciences
carbon
Chemical engineering
Desorption
Exact sciences and technology
human health
Mesoporous carbon coated monolith
Regeneration
sorption isotherms
temperature
β-carotene
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Summary:► β-carotene recovery studies form mesoporous carbon coated monolith (MCCM) were carried out by batch process. ► Desorption kinetics, equilibrium and regeneration of MCCM were studied. ► Homogeneous sites over the surface were actively involved in desorption. ► Desorption process is endothermic and diffusion might occur through micropores. ► For chemical and thermal processes, regeneration efficiency (RE%) after three consecutive cycles reduced to 60.04% and 81.62%, respectively. β-carotene, a natural antioxidant, beneficial form human health prospective. In this study we had examined the recovery of β-carotene form mesoporous carbon coated monolith (MCCM) by batch process. Desorption kinetics and isotherm studies were carried out by using n-hexane as an eluent. Isotherm studies showed better applicability of Langmuir model. The first-order two-compartment three-parameter kinetics model as a function of initial loading concentration and reaction temperature was applied. It was observed that β-carotene desorption process is controlled by both rapid and slow desorption. Results showed that the slow desorption fraction increases from 0.8446 to 0.9007 with increase in initial loading concentration from 10.83 to 39.72 mg/g while, the slow desorption fraction decreases from 0.9261 to 0.8684 with increase in reaction temperature form 30 to 50 °C. The activation energies for rapid and slow desorption were 7.88 and 44.47 kJ/mol, respectively. The regeneration studies were carried out by both chemical and thermal process. The regeneration efficiency (RE%) for the three consecutive cycles reduced from 96.24 to 60.04% and 94.51 to 81.62% for chemical and thermal regeneration processes, respectively.
ISSN:1385-8947
1873-3212
DOI:10.1016/j.cej.2011.08.015