Abderrahmane Kherbeche scite author profile

Abderrahmane Kherbeche

2Publications

88Citation Statements Received

78Citation Statements Given

How they've been cited

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Affiliations

Université Gustave Eiffel, Xi'an Jiaotong University, French National Centre for Scientific Research

Publications

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Ultra-Porous Nanocellulose Foams: A Facile and Scalable Fabrication Approach

Antonini

Zimmermann

et al. 2019

Nanomaterials

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Cellulose nanofibril foams are cellulose-based porous materials with outstanding mechanical properties, resulting from the high strength-to-weight ratio of nanofibrils. Here we report the development of an optimized fabrication process for highly porous cellulose foams, based on a well-controlled freeze-thawing-drying (FTD) process at ambient pressure. This process enables the fabrication of foams with ultra-high porosity, up to 99.4%, density of 10 mg/cm3, and liquid (such as oil) absorption capacity of 100 L/kg. The proposed approach is based on the ice-templating of nanocellulose suspension in water, followed by thawing in ethanol and drying at environmental pressures. As such, the proposed fabrication route overcomes one of the major bottle-necks of the classical freeze-drying approach, by eliminating the energy-demanding vacuum drying step required to avoid wet foam collapse upon drying. As a result, the process is simple, environmentally friendly, and easily scalable. Details of the foam development fabrication process and functionalization are thoroughly discussed, highlighting the main parameters affecting the process, e.g., the concentration of nanocellulose and additives used to control the ice nucleation. The foams are also characterized by mechanical tests and oil absorption measurements, which are used to assess the foam absorption capability as well as the foam porosity. Compound water-in-oil drop impact experiments are used to demonstrate the potential of immiscible liquid separation using cellulose foams.

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Multi-scale analysis of the influence of physicochemical parameters on the hydrodynamic and gas–liquid mass transfer in gas/liquid/solid reactors

Kherbeche

Milnes

Jimenez

et al. 2013

Chemical Engineering Science

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bubble hydrodynamics. A specific approach was proposed for estimating the mass transfer coefficient in such a configuration. It was found that the mass transfer coefficient kL depended on bubble behavior through the packing. Low porosity of packing, bubble size and velocity were the principal parameters influencing the hydrodynamics and mass transfer coefficients at this scale.This study considered a new approach to obtain precise data on biofilter systems, investigate the hydrodynamics and gas-liquid mass transfer at two scales, enriching the database on biofilters and providing new insights that could improve this system in industry.

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