Experimental Observation of Spin-Orbit Coherence Validates BSM-SG Electron Structure
Abstract:
A recent publication on Phys.org describes a groundbreaking observation of perfect spin-orbit coherence in electrons, defying conventional quantum mechanical expectations. In this article, we demonstrate how the BSM-SG (Basic Structures of Matter – Supergravitation) theory not only predicted such behavior decades ago, but also provides a concrete geometric and energetic explanation. We compare the newly observed phenomena with the BSM-SG FOHS (Fractal-Organized Helical Structure) electron model and discuss the implications for quantum computing and particle physics.
Introduction
In July 2025, a team of physicists reported a significant breakthrough: the detection of long-lasting spin-orbit coherence in electrons without measurable phase decoherence. The experiment was conducted at near-zero temperatures and involved precise spin-state manipulations, producing what the authors describe as a "quantum leap" in our understanding of electron behavior.
This observation challenges the foundations of the Standard Model, where electrons are considered point-like particles and quantum decoherence is expected to rapidly degrade spin-orbit entanglement.
In contrast, the BSM-SG theory has long proposed a structured vacuum and a geometrically complex electron, capable of exhibiting such coherence under proper environmental conditions.
BSM-SG FOHS Model Overview
According to BSM-SG, the electron is not a point particle, but a FOHS (Fractal-Organized Helical Structure), stabilized by the Cosmic Lattice (CL). The model introduces several key features:
- Helical Symmetry: The electron is formed by a double helical structure with intrinsic spin and magnetic moment vectors (SPM vectors).
- Lattice Interaction: The vacuum is a structured medium (CL) that interacts with the FOHS electron, providing energy stabilization and coherence.
- Spin-Orbit Coupling: In this model, spin and orbital motion are not separable; they are phase-locked via the SPM vectors and lattice constraints.
Comparison With the 2025 Observation
| Newly Observed Behavior | BSM-SG FOHS Model |
|---|---|
| Perfect spin-orbit coherence | Spin and orbital moment coupled by design |
| Suppressed phase decoherence | Stabilized by CL lattice and SPM vectors |
| Quantum leap for quantum computing | Predicted stable qubit via SG-ion states |
The experimental behavior mirrors the predictions made by BSM-SG decades ago. In particular, the observed resilience of the electron’s coherent state finds a direct explanation in the SPM stabilization inherent in the FOHS geometry.
Implications for Quantum Computing
The reported electron behavior offers a pathway to stable qubits. BSM-SG describes such stability via SG-stabilized ion states, precisely the type of structure we have prototyped in our Eternity quantum processor based on Yb:YAG crystals and InGaAs photodiodes.
In our own setup, using magnetic confinement and microwave phase-locking, we observe similar coherence patterns. This suggests that BSM-SG isn’t just a philosophical shift—it is an engineering blueprint for stable quantum information systems.
Conclusion
The so-called "holy grail" of electron behavior has been observed—but only BSM-SG provides the full physical mechanism. This reinforces the need to revise our particle models and integrate the Cosmic Lattice as a real structural component of space.
Future developments in quantum technologies, especially those seeking coherence beyond millikelvin domains, must embrace the FOHS electron model and structured vacuum principles.
Figures:
- Comparative Infographic – Newly Observed vs. BSM-SG Model
- FOHS Helical Electron Illustration
- Quantum Processor Prototype (Eternity) Schematic
Contact:
Victor Pronchev, Lead Researcher – Eternity Quantum Initiative