Physics at home-Easy double slit shows field

This experiment demonstrates forced wave behavior and ψ-field confinement by channeling coherent laser light through a cylindrical cavity lined with glitter paper. The internal glitter surface acts as a chaotic micro-mirror lattice, producing randomized internal reflections, refractive scattering, and dynamic path-length variations. When coherent light (such as a red or green laser) enters the cavity, it is forced into a complex interference pattern, generating speckle, standing waves, and intensity hotspots — visual manifestations of the light’s underlying wave nature.

By sealing the ends of the cavity with reflective and semi-reflective surfaces, a Fabry–Pérot-like structure is formed within a disordered boundary, enhancing wave confinement and recursive interference. The result is a fractal-like and time-varying light field, observable as speckled patterns on output screens or through visualization media such as fog or mist.

Vibrational modulation of the cavity wall using piezoelectric discs or acoustic drivers introduces external perturbation, enabling observation of dynamic ψ-field evolution under varying boundary pressure — effectively simulating vacuum shell compression and collapse within the KLTOE framework.

KLTOE Interpretation:
From the perspective of the Keith Luton Theory of Everything (KLTOE), this setup models a localized ψ-wave system under boundary deformation. The glitter cavity represents a tunable reflective boundary condition that traps and refracts energy into a confined vacuum shell, where standing wave nodes form high-density ψ-compression regions. Interference hotspots are interpreted as visible ψ-node collapses, offering a physical analog of vacuum pressure peaks and energy localization. This experiment provides a visual and experimental basis for KLTOE’s assertion that mass-energy structures emerge from boundary-driven vacuum compression fields.