Abdelhak Boussaid scite author profile

Abdelhak Boussaid

4Publications

35Citation Statements Received

6Citation Statements Given

How they've been cited

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140

Affiliations

University of Abou Bekr Belkaïd

Publications

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Temperature, pressure, and isotope effects on the structure and properties of liquid water: A lattice approach

Hakem¹,

Boussaid²,

Benchouk-Taleb³

2007

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We present a lattice model to describe the effect of isotopic replacement, temperature, and pressure changes on the formation of hydrogen bonds in liquid water. The approach builds upon a previously established generalized lattice theory for hydrogen bonded liquids [B. A. Veytsman, J. Phys. Chem. 94, 8499 (1990)], accounts for the binding order of 1/2 in water-water association complexes, and introduces the pressure dependence of the degree of hydrogen bonding (that arises due to differences between the molar volumes of bonded and free water) by considering the number of effective binding sites to be a function of pressure. The predictions are validated using experimental data on the temperature and pressure dependence of the static dielectric constant of liquid water. The model is found to correctly reproduce the experimentally observed decrease of the dielectric constant with increasing temperature without any adjustable parameters and by assuming values for the enthalpy and entropy of hydrogen bond formation as they are determined from the respective experiments. The pressure dependence of the dielectric constant of water is quantitatively predicted up to pressures of 2 kbars and exhibits qualitative agreement at higher pressures. Furthermore, the model suggests a--temperature dependent--decrease of hydrogen bond formation at high pressures. The sensitive dependence of the structure of water on temperature and pressure that is described by the model rationalizes the different solubilization characteristics that have been observed in aqueous systems upon change of temperature and pressure conditions. The simplicity of the presented lattice model might render the approach attractive for designing optimized processing conditions in water-based solutions or the simulation of more complex multicomponent systems.

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Heating of Biological Tissues by Gold Nano Particles: Effects of Particle Size and Distribution

Fasla¹,

Senoudi²,

Boussaid³

et al. 2011

JBNB

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Theory of microphase separation in charged crosslinked polymer blends with arbitrary charge distribution

Boussaid

Benhamou²,

Fazni³

2009

Eur. Phys. J. E

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In this paper, we are interested in the phase behavior and scattering properties of charged crosslinked polymer blends in solution. The system undergoes a microphase separation, below some critical temperature. To study such a transition, use is made of the standard de Gennes theory based on an analogy with a dielectric medium. This analogy is extended to include the effects of the initial composition fluctuations in order to improve its agreement with experimental data in the small wave vector range. The excluded-volume interactions are explicitly introduced through the blob model. The charge effects on the phase behavior are examined, for any charge distribution of polyions and for any salt concentration. This completes a previous study which was concerned with the situation where only one species is charged. The early kinetics of microphase separation is discussed, and the charges contribution to the growth rate is also evaluated.

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On the phase behavior and structural properties of polyelectrolyte solutions

Benmouna

Bouayed-Kazi

Boussaid

et al. 2009

European Polymer Journal

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