Radioactive Decay: Stochastic Half-Life | LG-331

[SFI-1.00] : BARE-METAL KINEMATICS // O(1) ENGINEERING.

Execution of the Radioactive Decay Tensor. At the quantum level, an unstable atom possesses no internal clock. It cannot "know" when it is going to decay; the process is entirely stateless and stochastic, governed flawlessly by the mathematical probability of exponential decay: N(t) = N₀e⁻λt.

This simulation visualizes the exact mechanical breakdown of a dense isotope matrix. 547 heavy parent nuclei start in a state of violent "Kinematic Fever" (C_DARK). As they individually cross their predetermined Weak Force thresholds, they violently eject either heavy Alpha Radiation (C_MAGENTA) or hyper-fast Beta Radiation (C_GOLD).

Once the instability energy is shed, the atom drops into its daughter isotope state (C_TITANIUM). It instantly becomes perfectly cold and absolutely motionless. Over 15 seconds, you watch the chaotic thermal energy of the entire lattice mathematically bleed out into a rigid, silent graveyard, tracked exactly by the HUD telemetry intersecting the theoretical half-life curve.

Entropy reversed via the Boomerang Matrix for an absolute 30.0-Second loop.
Daylight Protocol active. Zero-Temperature Telemetry tracked.

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