Computational Physics & the Future of Propulsion
Join the Propulsion mission, where computational physics, quantum gravity simulations, and next-generation engineering collide to explore the most advanced theoretical and experimental propulsion systems. This event will push the boundaries of nuclear and antimatter propulsion, anti-gravity, hypersonic travel by offering related insights into quantum information science and advanced solid-state materials science primarily, challenging participants to model the physics behind the impossible and turn it into the inevitable.
Simulate and analyze the expected propulsion signatures of hypersonic craft including plasma growth on heterogenous surfaces, shockwave formation, plasma interactions, and novel aerodynamic effects.
Develop computational frameworks for Alcubierre Drive-based systems and field-based propulsion mechanisms that challenge modeling aerodynamical bodies using classical physics.
Use computational electromagnetism such as circuit quantum electrodynamics (cQED) to simulate how UAPs interact with radar, gravitational fields, and atmospheric conditions. Investigate stealth physics, warp signatures, and exotic field effects.
Apply Wolfram Physics and AI driven computational mathematics to model the fundamental structure of space-time, searching for new physics theorems that could unlock next-generation propulsion principles.
| Generate new models for advanced propulsion with real-world testability.
| Provide AI-driven insights into advanced solid-state materials and energy systems.
| Expand our understanding of quantum field theory, general relativity, and atomic energy.
| Challenge known physics and uncover hidden pathways to propulsion beyond reaction-based systems.
| Physicists
| Engineers & AI/ML Engineers
| Computational Scientists
| Mathematicians
| Quantum Information Scientists
| Propulsion Enthusiasts
