Mineral Björn Hoiland

Vacuum Forge LabsQuantum/Theoretical Physics Solutions

Interactive 3D Simulations

Explore quantum physics and fusion energy through interactive 3D visualizations. Each simulation runs in real-time using WebGL and allows you to manipulate parameters to understand complex phenomena.

Featured Simulations

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Quantum Vacuum Catalyzation

Explore 3D vortex formation in Bose-Einstein Condensates (BECs) and their interaction with resonance fields and dipolar spin. Features interactive controls to manipulate vortex count, resonance frequency, quantum coupling, and temperature.

Topics: Zero-point energy, superfluidity, vortex dynamics, quantum coherence

⚡ Interactive sliders • 8K particles • Real-time physics

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Advanced FRC Reactor + QVC Physics

Beyond-standard-model FRC simulation featuring TAE harmonic modes, electron zitterbewegung trajectories, Dirac sea visualization, Schwinger limit pair production, and spin-correlated electron pairs. Explore quantum vacuum effects in fusion plasmas.

Topics: TAE modes, zitterbewegung, Dirac sea, Schwinger limit, vacuum polarization, electron pairing

🔬 7K particles • Interactive sliders • Virtual pair events • Real-time QED

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Quantum Vacuum Heterostructure Explorer

Explore a VdW bilayer hosting an excitonic BEC superfluid as an analog quantum vacuum. Features BKT vortex proliferation, Abrikosov lattices, synchrotron & Cherenkov radiation, Schwinger tunneling, chirality, phase-locking, and an Unruh-DeWitt detector probe.

Topics: BKT transition, Abrikosov lattice, chirality, synchrotron/Cherenkov radiation, Schwinger tunneling, Unruh effect, Dirac sea, ZPF, phase-locking

7K+ particles • 6 sliders • Mach cones • Phase-lock detection • Real-time QFT

About These Visualizations

All simulations run entirely in your browser using WebGL via Three.js and React Three Fiber. They provide real-time, hardware-accelerated 3D graphics to explore complex quantum and plasma physics phenomena.

System Requirements

Educational Purpose

These visualizations are designed to build intuition about quantum phenomena relevant to Quantum Vacuum Catalyzation theory and advanced fusion energy concepts. While simplified compared to research-grade simulations, they capture essential physics and allow interactive exploration of parameter spaces.

Note: These are illustrative models for educational purposes. Real experimental setups involve additional complexity and are governed by full quantum/plasma equations.