M
Mohamed Haboussi
Researcher at University of Paris
Publications - 54
Citations - 661
Mohamed Haboussi is an academic researcher from University of Paris. The author has contributed to research in topics: Finite element method & Constitutive equation. The author has an hindex of 12, co-authored 44 publications receiving 499 citations. Previous affiliations of Mohamed Haboussi include École normale supérieure de Cachan & University of Lorraine.
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Modélisation de fissures elliptiques internes par hybridation de fonctions de poids
TL;DR: Hachi et al. as discussed by the authors presented a methode ameliorant le calcul des facteurs d'intensite de contrainte par hybridation of deux fonctions de poids.
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Large Amplitude Free Vibration Analysis of Isotropic Curved Nano/Microbeams Using a Nonlocal Sinusoidal Shear Deformation Theory-Based Finite Element Method
TL;DR: In this article, the nonlinear flexural free vibration characteristics of size dependent curved isotropic nano/microbeams are studied using the nonlocal elasticity theory along with the sinus.
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A theory of inelasticity based on a non-equilibrium thermodynamic: application to yield surface prediction
TL;DR: In this article, a phenomenological approach is proposed to describe the inelastic behavior of a material based on the generalization of the Gibbs' relation outside from the equilibrium for uniform system.
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Local Stiffness Effect on Ferromagnetic Response of Nanostructure Arrays in Stretchable Systems (Phys. Status Solidi RRL 2/2019)
Nabil Challab,Fatih Zighem,Damien Faurie,Mohamed Haboussi,Mohamed Belmeguenai,Pierpaolo Lupo,A. O. Adeyeye +6 more
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Fatigue growth of embedded elliptical cracks using Paris-type law in a hybrid weight function approach
TL;DR: Hachi et al. as discussed by the authors proposed a hybrid weight function method (HWFM) for the prediction of embedded elliptical cracks in infinite bodies, where Paris's law of crack propagation was incorporated into the developed hybridization-based computer code, along with two degrees of freedom technique for managing the crack evolution and the cracked structure fatigue life.