Elamine ABDELOUAHED

Scopus Publications

Fatigue crack growth in notched 2024-T3 aluminum plate repaired with composite patch
Aicha Benchiha, Elamine Abdelouahed, Kouider Madani
Mechanics Based Design of Structures and Machines, 2026
A numerical investigation of mixed-mode crack propagation in fretting fatigue using a Stretching Finite Element Method
Aicha Benchiha, Elamine Abdelouahed, Soumia-Anfal Matoug, Fouzia Larbi-Chaht, Mohamed Mokhtari, et al.
Mechanics of Advanced Materials and Structures, 2026
Numerical Assessment of Pipeline Damage Due to an External Circumferential Semi-Elliptical Crack
Mohammed Amine Khater, Chaaban Aroussi, Elamine Abdelouahed, Bassam Gamal Nasser Muthanna, Mohamed Mokhtari, et al.
Diyala Journal of Engineering Sciences, 2025
This paper presents a numerical evaluation of pipeline damage caused by an external circumferential semi-elliptical crack. The study utilizes the Abaqus software and the Extended Finite Element Method (XFEM) to model and analyze the crack behavior. Various parameters such as crack size, internal pressure, and loading conditions are investigated to assess their influence on pipeline integrity. The results reveal that as internal pressure increases from 300 to 600 bar, the pipe’s bearing capacity significantly decreases due to heightened stress concentrations around crack tips, leading to increased hoop stress and Stress Intensity Factors (SIFs), which accelerate crack propagation. Higher pressures also promote crack nucleation and growth, further reducing the effective cross-sectional area and weakening the pipe's load-carrying ability. Additionally, the analysis highlights the critical influence of defect size (a/t ratio) on stress distribution and residual strength: as the a/t ratio increases, the pipe becomes more vulnerable to failure at lower stress levels. The critical crack size is identified at the intersection of the resistance curve and the ultimate stress line, beyond which failure occurs before reaching the material’s full strength. Non-physical regions, where resistance exceeds ultimate stress, are disregarded to ensure realistic defect assessments. Under an internal pressure of 30 MPa, pipes with a/t ratios of 0.50 and 0.62 remain within the safety zone, while those with a/t ratios of 0.75 and 0.80 enter the failure zone, indicating a substantial loss of structural integrity and an increased risk of fracture.
Using FGM concept and combined of XFEM-CZM technics to predict the damage in carbon/carbon-epoxy graded composites
I. M. A. Ghermaoui, M. Mokhtari, H. Benzaama, A. Elamine
Mechanics of Advanced Materials and Structures, 2024
The study and the proposal of the concepts of reinforcement in the notched structures, present an objective for many researchers. Recently, the use of bi-materials and graduated materials limits the choice to have more graduation concepts, except that the UD (uni-directional) fiber composites limit the choice to have more grading concepts. Through the finite element method and using the ABAQUS computer code, the main objective of this work is to analyze the damage of the graded Carbon/Carbon-Epoxy composite, using the FGM concept. This composite IM7/8552 in two qualities of fibers housed in the same epoxy matrix named CFRP-1 and CFRP-2, is graduated by row of finite elements to the size of fiber diameters according to the thickness. This approximation of the real behavior with more precision in the graduation is carried out by a proposed meshing technique, which gives a combination between XFEM and CZM. The CZM layers are introduced according to the thickness between the rows of finite elements. The graduation is in the volume of fibers between these two qualities, remains constant in the composite at 60%. A volume fraction exponent named (n) gives it. The response and the damage under the effect of different CFRP graduation parameters have been highlighted in this work by force-displacement and crack propagation path curves.
Damage analysis of hybrid carbon/Glass-Epoxy pipe elbows under bending and pressure loading
Fatna Telli, Mohamed Mokhtari, Mohamed EL Amine Khiari, Benzaama Habib, Amir Slamene, et al.
Mechanics of Advanced Materials and Structures, 2024
Given their many advantages, composite materials have always proven their effectiveness. As in aeronautical structures where reinforcement techniques are used, their application is widened in various fields. Analyzing these composite structures or proposing new concepts for reinforcements remains an interest of several researchers. This work opts for the use of a hybrid composite of a tubular structure of an elbow attached by straight parts. The structural composite is twill. The aim of the elbow damage study is to evaluate the proposed reinforcement concept. The stiffness and damage parameters of the plies are introduced at the size of the fiber and according to the thickness per row of finite elements, hence the use of an adequate meshing technique. The linear behavior follows the equivalent stress flow theory of Von Mises. The results presented as moment-rotation curves were evaluated under design effect and bending moment mode. Depending on the loading conditions, the proposed concept of the hybrid composite showed an overcapacity of resistance where the location of the fiber qualities played the optimization of this capacity. The structure has shown even more resistance for certain locations of the folds which are reinforced in thickness. Depending on the bending moment mode applied, the results show that the damage is caused at very low deformations by ovalization of the elbow and in fiber tension.
Numerical Finite Element Analysis of Cracked Stainless-Steel Pipe Repaired by GFRP in a Moist Environment
Abdelouahed Elamine, Sadek Kaddour, Benaoumeur Aour, Habib Benzaama, Mohammed Salah Bennouna, et al.
International Journal of Engineering Research in Africa, 2024
Bonding metallic structures with composite materials is widely considered to be the most optimal method for joining damaged and fractured structures. This method offers important advantages, such as reducing the stress intensity factor (SIF) and increasing the lifetime of the joined structure. However, hygrothermal aging is a phenomenon that can reduce the lifetime of reinforced structures made of glass fiber-reinforced polymer (GFRP). This study used numerical modeling to investigate a cracked stainless steel pipe operating in a hygrothermal environment and repaired with three patches. The main objective of this work is to determine the effect of adhesive aging due to hygrothermal damage on the repair efficiency of a cracked SA312 type 304 stainless steel pipe. The Finite Element Method (FEM) is used to evaluate the SIF as a function of applied load for different immersion times and at two different temperatures. First, the developed model was validated against literature results. A parametric study was then carried out. The obtained results showed that the adhesive maintains its stiffness for 7.5 months of immersion and that the mechanical properties of the adhesive are acceptable even at temperatures of 90°C or lower and internal pressures less than or equal to 50 bar. However, when the pressure load exceeds 50 bar (pint > 50 bar), the degradation of the adhesive becomes more significant, and the hygrothermal aging leads to variations in the mechanical properties of the joined structure. It is important to note that these results can contribute to the improvement of the existing composite repair design standard and can provide reliability for the application of GFRP in different humid environments.
Using XFEM technique to predict the crack growth in the notched plate under high loading cyclic conditions
Djezouli Moulai-Khatir, Mohamed Mokhtari, Amir Slamene, Elamine Abdelouahed, Habib Benzaama, et al.
Mechanics of Advanced Materials and Structures, 2024
Our study delves into analyzing fatigue damage in notched structures, an essential field in structural mechanics. We aim to understand how geometric and dimensional variations in the notches affect fatigue damage under different modes and amplitudes of cyclic loading, focussing on the behavior of steel. Our research methodology integrates experimental and numerical approaches. Experimental validation encompasses material properties, mesh selection, and boundary conditions. The finite element method is tailored to address steel’s elastoplastic behavior, employing calibrated parameters for kinematic and isotropic cyclic hardening models within the numerical realm. Specific findings elucidate the cyclic response of notched structures, tracking damage progression to critical thresholds, including the number of cycles to failure (Nf) and the critical crack length (Lc). Hysteresis curves vividly depict stress–strain relationships, offering insight into material behavior under cyclic loading. Implications span engineering domains, focussing on reliability and durability in the aerospace, automotive, and civil engineering sectors. Future directions include real-world applications and advanced techniques such as the Extended Finite Element Method (XFEM). In conclusion, this research enriches our understanding of fatigue damage analysis in notched structures, poised to impact safety and robust engineering design.
EFFECT OF THE INFLUENCE OF THE DIFFERENT CORROSION LEVEL ON THE REPAIR EFFICIENCY OF MARINE AND OFFSHORE STRUCTURES BY BONDED COMPOSITE
Journal of Theoretical and Applied Mechanics Bulgaria, 2024
Using a UMM-XFEM technics to predict the damage in CFRP bi-graded with glass-epoxy materials of notched plate under quasi-static loading
Abdallah Benzaama, Mohamed Mokhtari, Nour-El-Imene Ahmed-Bouziane, Elamine Abdelouahed, Benzaama Habib, et al.
Mechanics of Advanced Materials and Structures, 2024
Composite materials, with their remarkable advantages in various industrial sectors, have increasingly broadened their applications, particularly in the reinforcement of notched structures. These still attract the intention of many researchers to analyze them is to improve them. Indeed, the study of their reinforcements can only be done by studying their damage. Depending on the proposed reinforcement, it can take several images; such as geometric or material, total or partial at the stat of the notch. Through a numerical prediction, our objective in this work consists in a total reinforcement of the structure by proposed materials called CFRP bi-graded with glass-epoxy. Following the proposed graduation design, these three different fiber qualities pooled a single quality in the middle for each design case. This is possible provided that these fibers are housed in the same matrix in epoxy quality and with the same volume in volume fraction. The parameters of rigidity and the graded damage in the structure are homogenized according to the thickness by volume fraction introduced by finite elements using technique UMM-XFEM. For this, a special mesh is used. Where the parameters evaluated such as the type and the density of finite elements as well as the architecture of mesh and the adequacy with the criterion of the damage and these parameters introduced, all showed an effect on the determined results. The linear constitutive law of our model agrees with the equivalent stress flow theory of Von Mises. The composite used in this work in CFRP is of quality IM7/8552. The evaluation under the effect of the graduation parameters is made on the response of the structure and its resistance capacity using the tensile separation curves. The study showed that the proposed concept, in the case where the strongest fiber is in the middle of the plate, a symmetrical stress with respect to the thickness of the structure and an overcapacity in its resistance. This resistance overcapacity becomes significant due to the effect of the graduation volume fraction index (β) chosen. The coupling of the XFEM technique with that of UMM has effectively shown the separation of the structure after crack initiation in structures with graded materials. Where It is also shown that the critical length which corresponds to the total failure of the proposed composite material is the average of the critical lengths of the graded layers. The damage under the effect of different concepts was highlighted in this work.
Using a non-linear mixed model behavior of CZM to predict the damage in single lap bonded joint with Bi-composite graded materials
Elamine Abdelouahed, Mohamed Mokhtari, Benzaama Habib, Ilias-Mohammed-Amine Ghermaoui, Mohammed-Chams-Eddine Ezzine, et al.
Mechanics of Advanced Materials and Structures, 2024
The present work is a numerical prediction based initially on a reliable model validated by experiments under the same conditions used as ours with new concepts in Bi-composite plates. A system formulation approach of the adhesive in ductile and nonlinear damage behavior is used in this analysis This ductility is developed by the CZM technique implemented using the MATLAB program in ABAQUS computer code. For a numerical prediction of the ductile behavior of the adhesive, the CZM model is an extension of the pure modes (I and II) previously characterized in block by tests. This extension is trapezoidal in increasing stresses of the adhesive in its behavior law. The single lap joint configuration allows us to stress the glue joint to mixed-mode loading. The resistance of the assembled structures remains conditioned by the behavior of the adhesive until it is damaged and the rigidity of the attached plates. Therefore, our objective in this work is to cause the plasticization damage of the adhesive at different responses and levels. For this, the bi-composite graduation in concept and in graduation index largely plays the role of evaluation parameters. In order to test the adequacy for a good resistance, three different concepts of graduation in Bi-composite were proposed such as: concept1-concept1, concept2-concept2, and simple concept-simple concept. By these two cases of assemblies, these concepts have the advantage of having different assembly possibilities, The proposed concepts of graduated bi-composite plates showed an overcapacity of resistance on the assembly. The latter becomes important in the adequacy of concept of these assembled plates. Similarly, the results show that different responses and levels cause the damage by effect of these concepts.
Sensitivity analysis of GTN damage parameters: Application to notched plate ductile fracture simulation
Sadek Gouasmi, Mohamed Mokhtari, Amir Slamene, Billel Hamza, Habib Benzaama, et al.
Mechanics of Advanced Materials and Structures, 2024
Nonlinear CZM-based predictive analysis of damage in single-lap composite joints: An exploration of the FGM concept in Fiber–Matrix coupling
Fatima Zohra Messabih, Mohamed Mokhtari, Mohamed Bentoumi, Amir Slamene, Elamine Abdelouahed, et al.
Mechanics of Advanced Materials and Structures, 2024
Using Functionally Graduated Materials Concept to Predict the Damage of Heat-Treated Elbows Under Bending and Pressure Loading
Fatna Telli, Mohamed Mokhtari, Elamine Abdelouahed, Habib Benzaama, Kaoutar Khedim
Journal of Pressure Vessel Technology, 2023
Using XFEM Technique to Predict the Effect of Default on the Damage of Steel Pipe Reduced-Connection Under Bending and Pressure Loading
Abdelaziz Ahmed-Bensoltane, Mohamed Mokhtari, Habib Benzaama, Khaled Samet, Hamza Benrouba, et al.
International Journal of Steel Structures, 2023
Using XFEM to predict the damage with temperature of the steel pipe elbows under bending and pressure loading
Nourddine Hammadi, Moahmed Mokhtari, Habib Benzaama, Kouider Madani, Abdelkader Brakna, et al.
Frattura Ed Integrita Strutturale, 2021
Finite element analysis of the thermo-mechanical behavior of composite pipe elbows under bending and pressure loading
Elamine Abdelouahed, M. Mokhtari, H. Benzaama
Frattura Ed Integrita Strutturale, 2019
Pipeline repair by composite patch under temperature and pressure loading
Elamine Abdelouahed, H. Benzaama, M. Mokhtari, B. Aour
Frattura Ed Integrita Strutturale, 2019
Using XFEM techniques to predict the damage of aluminum 2024T3 notched under tensile load
Abdallah Benzaama, Mohamed Mokhtari, Habib Benzaama, Elamine Abdelouahed, Tawfik Tamine, et al.
Frattura Ed Integrita Strutturale, 2019

RECENT SCHOLAR PUBLICATIONS

A numerical investigation of mixed-mode crack propagation in fretting fatigue using a Stretching Finite Element Method
A Benchiha, E Abdelouahed, SA Matoug, F Larbi-Chaht, M Mokhtari, ...
Mechanics of Advanced Materials and Structures 33 (1), 2660322 , 2026
2026
Fatigue crack growth in notched 2024-T3 aluminum plate repaired with composite patch
A Benchiha, E Abdelouahed, K Madani
Mechanics Based Design of Structures and Machines 54 (1), 2555421 , 2026
2026
Citations: 1
Numerical Assessment of Pipeline Damage Due to an External Circumferential Semi-Elliptical Crack
MA Khater, C Aroussi, E Abdelouahed, BGN Muthanna, M Mokhtari, ...
Diyala Journal of Engineering Sciences, 73-82 , 2025
2025
Damage analysis of hybrid carbon/glass-epoxy pipe elbows under bending and pressure loading
F Telli, M Mokhtari, MELA Khiari, B Habib, A Slamene, E Abdelouahed
Mechanics of Advanced Materials and Structures 31 (24), 6196-6212 , 2024
2024
Citations: 20
Using XFEM technique to predict the crack growth in the notched plate under high loading cyclic conditions
D Moulai-Khatir, M Mokhtari, A Slamene, E Abdelouahed, H Benzaama, ...
Mechanics of Advanced Materials and Structures 31 (27), 9241-9259 , 2024
2024
Citations: 25
Sensitivity analysis of GTN damage parameters: application to notched plate ductile fracture simulation
S Gouasmi, M Mokhtari, A Slamene, B Hamza, H Benzaama, ...
Mechanics of Advanced Materials and Structures 31 (27), 9191-9199 , 2024
2024
Citations: 15
Nonlinear CZM-based predictive analysis of damage in single-lap composite joints: An exploration of the FGM concept in Fiber–Matrix coupling
FZ Messabih, M Mokhtari, M Bentoumi, A Slamene, E Abdelouahed, ...
Mechanics of Advanced Materials and Structures 31 (27), 8937-8947 , 2024
2024
Citations: 16
Using FGM concept and combined of XFEM-CZM technics to predict the damage in carbon/carbon-epoxy graded composites
IMA Ghermaoui, M Mokhtari, H Benzaama, A Elamine
Mechanics of Advanced Materials and Structures 31 (25), 7526-7544 , 2024
2024
Citations: 21
Using a UMM-XFEM technics to predict the damage in CFRP bi-graded with glass-epoxy materials of notched plate under quasi-static loading
A Benzaama, M Mokhtari, NEI Ahmed-Bouziane, E Abdelouahed, ...
Mechanics of Advanced Materials and Structures 31 (25), 7367-7385 , 2024
2024
Citations: 19
Using a non-linear mixed model behavior of czm to predict the damage in single lap bonded joint with bi-composite graded materials
E Abdelouahed, M Mokhtari, B Habib, IMA Ghermaoui, MCE Ezzine, ...
Mechanics of Advanced Materials and Structures 31 (25), 7180-7194 , 2024
2024
Citations: 22
Numerical Finite Element Analysis of Cracked Stainless-Steel Pipe Repaired by GFRP in a Moist Environment
E Abdelouahed, K Sadek, B Aour, H Benzaama, MS Bennouna, ...
International Journal of Engineering Research in Africa 70, 1-18 , 2024
2024
Citations: 1
Effect of the influence of the different corrosion level on the repair efficiency of marine and offshore structures by bonded composite
B Belarbi, BM Salah, K Sadek
Journal of Theoretical and Applied Mechanics 54 (3), 308-322 , 2024
2024
Citations: 1
Predicting Damage in Single-Lap Composite Joints with Nonlinear CZM behaviour using FGM Concept in Fibre-Matrix Coupling Laws
FZ Messabih, M Mokhtari, M Bentoumi, A Slamene, E Abdelouahed, ...
2023
Using functionally graduated materials concept to predict the damage of heat-treated elbows under bending and pressure loading
F Telli, M Mokhtari, E Abdelouahed, H Benzaama, K Khedim
Journal of Pressure Vessel Technology 145 (4), 041001 , 2023
2023
Citations: 14
Using XFEM technique to predict the effect of default on the damage of steel pipe reduced-connection under bending and pressure loading
A Ahmed-Bensoltane, M Mokhtari, H Benzaama, K Samet, H Benrouba, ...
International Journal of Steel Structures 23 (1), 316-330 , 2023
2023
Citations: 16
Using XFEM to predict the damage with temperature of the steel pipe elbows under bending and pressure loading
N Hammadi, M Mokhtari, H Benzaama, K Madani, A Brakna, ...
Fracture and Structural Integrity 15 (55), 345-359 , 2021
2021
Citations: 6
Using XFEM Techniques to Predict the Damage of aluminum 2024T3 notched under tensile load.
B Abdallah, M Mohamed, B Habib, A Elamine, T Tawfik, M Kouider, ...
Fracture & Structural Integrity , 2019
2019
Using XFEM Techniques to Predict the Damage of aluminum 2024T3 notched under tensile load
A Benzaama, M Mokhtari, H Benzaama, E Abdelouahed, T Tamine, ...
Fracture and Structural Integrity 13 (50), 184-193 , 2019
2019
Citations: 12
Pipeline repair by composite patch under temperature and Pressure loading
BA E Abdelouahed, H BENZAAMA, M MOKHTARI
Frattura ed Integrità Strutturale 13 (49), 690-697 , 2019
2019
Citations: 15
Finite Element Analysis of the Thermo-Mechanical Behavior of Composite Pipe Elbows under Bending and Pressure Loading
HB E ABDELOUAHED, M MOKHTARI
Frattura ed Integrità Strutturale 13 (49), 698-713 , 2019
2019
Citations: 24

MOST CITED SCHOLAR PUBLICATIONS

Using XFEM technique to predict the crack growth in the notched plate under high loading cyclic conditions
D Moulai-Khatir, M Mokhtari, A Slamene, E Abdelouahed, H Benzaama, ...
Mechanics of Advanced Materials and Structures 31 (27), 9241-9259 , 2024
2024
Citations: 25
Finite Element Analysis of the Thermo-Mechanical Behavior of Composite Pipe Elbows under Bending and Pressure Loading
HB E ABDELOUAHED, M MOKHTARI
Frattura ed Integrità Strutturale 13 (49), 698-713 , 2019
2019
Citations: 24
Using a non-linear mixed model behavior of czm to predict the damage in single lap bonded joint with bi-composite graded materials
E Abdelouahed, M Mokhtari, B Habib, IMA Ghermaoui, MCE Ezzine, ...
Mechanics of Advanced Materials and Structures 31 (25), 7180-7194 , 2024
2024
Citations: 22
Using FGM concept and combined of XFEM-CZM technics to predict the damage in carbon/carbon-epoxy graded composites
IMA Ghermaoui, M Mokhtari, H Benzaama, A Elamine
Mechanics of Advanced Materials and Structures 31 (25), 7526-7544 , 2024
2024
Citations: 21
Damage analysis of hybrid carbon/glass-epoxy pipe elbows under bending and pressure loading
F Telli, M Mokhtari, MELA Khiari, B Habib, A Slamene, E Abdelouahed
Mechanics of Advanced Materials and Structures 31 (24), 6196-6212 , 2024
2024
Citations: 20
Using a UMM-XFEM technics to predict the damage in CFRP bi-graded with glass-epoxy materials of notched plate under quasi-static loading
A Benzaama, M Mokhtari, NEI Ahmed-Bouziane, E Abdelouahed, ...
Mechanics of Advanced Materials and Structures 31 (25), 7367-7385 , 2024
2024
Citations: 19
Nonlinear CZM-based predictive analysis of damage in single-lap composite joints: An exploration of the FGM concept in Fiber–Matrix coupling
FZ Messabih, M Mokhtari, M Bentoumi, A Slamene, E Abdelouahed, ...
Mechanics of Advanced Materials and Structures 31 (27), 8937-8947 , 2024
2024
Citations: 16
Using XFEM technique to predict the effect of default on the damage of steel pipe reduced-connection under bending and pressure loading
A Ahmed-Bensoltane, M Mokhtari, H Benzaama, K Samet, H Benrouba, ...
International Journal of Steel Structures 23 (1), 316-330 , 2023
2023
Citations: 16
Sensitivity analysis of GTN damage parameters: application to notched plate ductile fracture simulation
S Gouasmi, M Mokhtari, A Slamene, B Hamza, H Benzaama, ...
Mechanics of Advanced Materials and Structures 31 (27), 9191-9199 , 2024
2024
Citations: 15
Pipeline repair by composite patch under temperature and Pressure loading
BA E Abdelouahed, H BENZAAMA, M MOKHTARI
Frattura ed Integrità Strutturale 13 (49), 690-697 , 2019
2019
Citations: 15
Using functionally graduated materials concept to predict the damage of heat-treated elbows under bending and pressure loading
F Telli, M Mokhtari, E Abdelouahed, H Benzaama, K Khedim
Journal of Pressure Vessel Technology 145 (4), 041001 , 2023
2023
Citations: 14
Using XFEM Techniques to Predict the Damage of aluminum 2024T3 notched under tensile load
A Benzaama, M Mokhtari, H Benzaama, E Abdelouahed, T Tamine, ...
Fracture and Structural Integrity 13 (50), 184-193 , 2019
2019
Citations: 12
Using XFEM to predict the damage with temperature of the steel pipe elbows under bending and pressure loading
N Hammadi, M Mokhtari, H Benzaama, K Madani, A Brakna, ...
Fracture and Structural Integrity 15 (55), 345-359 , 2021
2021
Citations: 6
Réparation par patch composite des pipelines sous charge de la pression interne
E Abdelouahed, H Benzaama, B Aour, M Mokhtari, AA Tadjeddine
24ème Congrès Français de Mécanique , 2019
2019
Citations: 2
Fatigue crack growth in notched 2024-T3 aluminum plate repaired with composite patch
A Benchiha, E Abdelouahed, K Madani
Mechanics Based Design of Structures and Machines 54 (1), 2555421 , 2026
2026
Citations: 1
Numerical Finite Element Analysis of Cracked Stainless-Steel Pipe Repaired by GFRP in a Moist Environment
E Abdelouahed, K Sadek, B Aour, H Benzaama, MS Bennouna, ...
International Journal of Engineering Research in Africa 70, 1-18 , 2024
2024
Citations: 1
Effect of the influence of the different corrosion level on the repair efficiency of marine and offshore structures by bonded composite
B Belarbi, BM Salah, K Sadek
Journal of Theoretical and Applied Mechanics 54 (3), 308-322 , 2024
2024
Citations: 1
A numerical investigation of mixed-mode crack propagation in fretting fatigue using a Stretching Finite Element Method
A Benchiha, E Abdelouahed, SA Matoug, F Larbi-Chaht, M Mokhtari, ...
Mechanics of Advanced Materials and Structures 33 (1), 2660322 , 2026
2026
Numerical Assessment of Pipeline Damage Due to an External Circumferential Semi-Elliptical Crack
MA Khater, C Aroussi, E Abdelouahed, BGN Muthanna, M Mokhtari, ...
Diyala Journal of Engineering Sciences, 73-82 , 2025
2025
Predicting Damage in Single-Lap Composite Joints with Nonlinear CZM behaviour using FGM Concept in Fibre-Matrix Coupling Laws
FZ Messabih, M Mokhtari, M Bentoumi, A Slamene, E Abdelouahed, ...
2023

Elamine ABDELOUAHED

RESEARCH, TEACHING, or OTHER INTERESTS

Scopus Publications

RECENT SCHOLAR PUBLICATIONS

MOST CITED SCHOLAR PUBLICATIONS