Probability the packet crosses the barrier.
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Hardware-constrained learning for quantum computing and artificial intelligence
Simulation studio
Vary barrier width, barrier height, and packet energy to see when transmission collapses and when wave behavior still leaks through.
The lab is designed as an intuition-builder for why quantum transport differs from a classical particle model at the same energy budget.
Subject context
Explore state geometry, superposition, interference, tunneling, entanglement, and measurement collapse through visual-first interactive labs.
Live lab
These academy-style labs are designed as compact, browser-playable teaching surfaces: enough interaction to make the core idea legible, without pretending to be a full research workbench.
Interactive academy lab
Model the barrier as a tunable gatekeeper: as width or height rises, classical intuition says stop, but the quantum tail can still leak through.
Controls
Outputs
Probability the packet crosses the barrier.
Probability reflected back toward the source.
Qualitative penetration depth inside the barrier.
Even below the barrier, non-zero transmission survives because the wavefunction decays continuously rather than stopping at a hard classical wall.
What this teaches
The lab is designed as an intuition-builder for why quantum transport differs from a classical particle model at the same energy budget.
Vary barrier width, barrier height, and packet energy to see when transmission collapses and when wave behavior still leaks through.
Keep exploring