Atif Khan

Master of Engineering graduate specializing in Advanced Fatigue and Fracture Analysis, Finite Element Analysis (FEA), and Stress Analysis. Proven ability to apply technical skills in mechanical design and analysis, with a strong foundation in fatigue analysis, stress modeling, and material testing for engineering projects. Experienced in managing large-scale projects with strong project management and logistical coordination skills. Eager to contribute to innovative aerospace solutions by leveraging technical knowledge and problem-solving abilities.

• Finite Element Analysis of Bridge Structure: Conducted finite element analysis (FEA) on a bridge structure to evaluate stress distribution and overall structural integrity. Utilized ANSYS for detailed simulation, contributing to the optimization of the bridge design and ensuring structural stability.
• Fatigue and Creep Behavior of Titanium Alloys at High Temperature Conditions: Performed an in-depth literature review on the fatigue and creep behavior of titanium alloys under high-temperature conditions. Evaluated existing research to determine critical factors affecting material performance, and formulated actionable insights and recommendations to guide future research directions and practical applications
• Damage evaluation using C-Scan for impacted composite structures: Executed damage assessment on sandwich composite laminates subjected to impact using Ultrasonic C-Scan technology. Developed expertise in solid mechanics and composite materials, interpreting results to assess and ensure structural integrity following impact events.

• Advanced Fatigue Fracture Analysis: Focused on fatigue failure and fracture mechanics in engineering components subjected to monotonic and cyclic loading. Topics included Low Cycle Fatigue (LCF) and High Cycle Fatigue (HCF), stress intensity factors, J-integral analysis, and fatigue crack initiation and growth. Covered fatigue life prediction using the Coffin-Manson equation, as well as analysis of both notched and un-notched components under uniaxial and multi-axial loading conditions. Utilized practical case studies for structural damage assessment and failure analysis.
• Fracture Mechanics: Covered the principles of engineering fracture mechanics, with a focus on crack growth, Griffith energy criteria, and linear elastic fracture mechanics (LEFM). Key topics included stress intensity factors, plastic zones, fatigue cracking, elastic-plastic fracture, the J-integral, and mixed-mode fracture analysis
• Finite Element Analysis: Explored the formulation and implementation of the Finite Element Method (FEM) in engineering applications. Covered variational and weighted residual methods, various element types (linear, quadratic, isoparametric, hybrid), and numerical methods for spatial integration, linear algebraic equations, and eigenvalue evaluation. Utilized ANSYS for practical applications and simulations