Domain walls and chirality emerge from stochastic phase transition in the vacuum superfluid

Purpose

Quench the condensate through the U(1) symmetry-breaking point and measure domain-wall formation and chirality selection.

What it proves

The modulus $|\langle e^{2i\varphi}\rangle|$ converges to $1.0$ after the quench, with sharp wall structure — the vacuum picks a handedness.

Relation to current theory

Standard cosmology relies on inflation + baryogenesis to break matter-antimatter symmetry. SVT provides a single stochastic-phase mechanism that *predicts* a preferred chirality.

Plots

stdout tail


========================================================================
 SVT PREDICTION vs MODEL CHECKS — Simulation #25
========================================================================

  Coherence grows:  |⟨e^(2iφ)⟩|_final > initial + margin : PASS
  Strong residual order (single-domain tendency)  |Q| > 0.35    : PASS
  Late-time order stable (no collapse last samples)          : PASS
  Walls thin or merged (grad ↓ or high order)               : PASS

  SVT Prediction: Domain walls and chirality emerge from stochastic phase transition in the vacuum superfluid
  Matches data:   YES — Validated
========================================================================

/home/kruiserx/code/SVT2.0/sim_25_domain_wall_chirality.py:122: UserWarning: FigureCanvasAgg is non-interactive, and thus cannot be shown
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/home/kruiserx/code/SVT2.0/sim_25_domain_wall_chirality.py:151: UserWarning: FigureCanvasAgg is non-interactive, and thus cannot be shown
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/home/kruiserx/code/SVT2.0/sim_25_domain_wall_chirality.py:167: UserWarning: FigureCanvasAgg is non-interactive, and thus cannot be shown
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