Turning the Clock Backwards: Towards the Supersonic Future - Gargi Dashora

Florida State University
2026
Supersonic Flight
aerospace engineering
Concorde
Aerodynamics
Aircraft Engines
fluid dynamics
computational modeling
Supercomputing
aviation
Hypersonics
Airflow Simulation
turbulence
Atmospheric Physics
Engine Failure
Computational Fluid Dynamics
CFD
Aerospace Research
aviation safety
Propulsion Systems
High-Speed Flight
Flight Engineering
Mechanical Engineering
Shock Waves
Engine Stability
aircraft design
Atmospheric Conditions
Flow Instability
Aviation Technology
Numerical Simulation
Sonic Boom
Flight Mechanics
Turbine Engines
Fluid Mechanics
High Performance Computing
FSU Supercomputers
Engine Dynamics
Aviation Innovation
sustainable aviation
Aerospace Technology
Supersonic Transport

This research investigates why supersonic aircraft engines fail under turbulent atmospheric conditions. Using high-performance supercomputer simulations, the study models airflow disruptions around supersonic engines to identify early warning signs of instability. The work aims to improve engine reliability and help revive safe, efficient supersonic passenger air travel.

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