A5085050099- Combustion and flame dynamics
- Advanced Numerical Methods in Computational Mathematics
- Cardiac electrophysiology and arrhythmias
- Electromagnetic Simulation and Numerical Methods
- Semiconductor materials and devices
- Mechanical stress and fatigue analysis
- Electromagnetic Scattering and Analysis
- Fire dynamics and safety research
- Advanced Mathematical Modeling in Engineering
- MXene and MAX Phase Materials
- Semiconductor materials and interfaces
- Radiative Heat Transfer Studies
- Cardiovascular Function and Risk Factors
- Fluid Dynamics and Turbulent Flows
- Numerical methods in engineering
- Elasticity and Material Modeling
- Lattice Boltzmann Simulation Studies
- Contact Mechanics and Variational Inequalities
- Heat Transfer Mechanisms
Universitat Politècnica de Catalunya
2016-2022
Barcelona Supercomputing Center
2016-2022
KTH Royal Institute of Technology
2020
Autonomous University of Yucatán
2007
Abstract In this work, we present a fully coupled fluid‐electro‐mechanical model of 50th percentile human heart. The is implemented on Alya, the BSC multi‐physics parallel code, capable running efficiently in supercomputers. Blood cardiac cavities modeled by incompressible Navier‐Stokes equations and an arbitrary Lagrangian‐Eulerian (ALE) scheme. Electrophysiology with monodomain scheme O'Hara‐Rudy cell model. Solid mechanics total Lagrangian formulation for discrete strains using...
The presented work addresses the investigation of heat loss a confined turbulent jet flame in labscale combustor using conjugate-heat transfer approach and large-eddy simulation.The analysis includes assessment principal mechanisms this combustion chamber: radiation, convection conduction over walls.A staggered is used to couple reactive flow field through solid both domains are solved two implementations same code.Numerical results compared against experimental data an thermal boundary...