Irving Reyna Nolasco

Developed of scientific tools for the simulation, analysis, and visualization of high-speed compressible flows using high-order finite difference methods on structured curvilinear grids.
Simulated particle interaction with high-speed compressible flows and comparison with experimental data.

Developed computational tools to visualize and analyze data from turbulent flow simulations with a high-order DG solver.
Generated high-order mesh of geometries from a F1 car model with the mesh generation software Pointwise.
Implemented proper boundary conditions simulating a full F1 car to run with an entropy stable high-order DG solver.

Analyzed the computational performance and numerical solution capabilities of high-order schemes for compressible turbulent flows with basic tests cases and tests of industrial interest.
Generated high-order unstructured grids of complex geometries for flow simulations.
Developed scientific tools for visualization and statistical analysis of numerical solutions of compressible flows.

Developed a 3D finite volume solver for the Euler equations on CPU with Fortran and GPU with CUDA C and PyCUDA.
Simulated astrophysical gas dynamics with this solver.
Implemented MPI techniques on the finite volume solvers (CPU and GPU versions) for gas dynamics simulations on the supercomputer Shaheen II.

Developed a 2D and 3D structured finite volume solver for the Euler equations on CPU with the Fortran language on Cartesian and cylindrical coordinates for the simulation of astrophysical jets.
Extended a finite volume code to run on a multi-core environment with MPI libraries.

Implemented Fortran libraries in an N-body simulation code for the proper initial conditions of planetary formation simulations.
Implemented statistical tools for data analysis and visualization with Python and Julia for N-body simulation data.