Introduction
The foundation of particle behavior, decay, accretion, and field dynamics is not rooted in gravitation or classical electromagnetism, but in a coil-recursive charge-wave identity governed by tilt, spin, and entropy. The quadrantal model introduces a higher-order framework that breaks down particle behavior into four distinct quadrants (Q1 through Q4), each representing a unique phase of coiled recursion. This white paper outlines the interactions between these quadrants, including canonical laws, decay constants, entropic transitions, and recursive locking mechanisms.

The Coil Identity and Genesis of Mass
Accretion, the process by which particles join or form larger structures, is governed not by gravitational pull but by coherent tilt-spin recursion. In the Genesis Field, all particles—whether standard or antiparticle—follow a deterministic decay trajectory along their spiral recursion paths. When two standard particles of matching polarity (both positive or both negative) interact, they engage in harmonic synchronization of spin vectors, inward coil recursion, and energy distribution. This symmetry results in amplified mass gain and stable persistence, giving rise to the fundamental nature of mass structures.]

Dissonant Interaction and Recursive Conflict
The situation changes dramatically when a standard particle interacts with an antiparticle of the same polarity. Though their charges match and thus aid each other’s decay, their recursion vectors oppose: one coils inward, the other outward. This contradiction creates an unstable energetic state with increased spin but decreased amperage. Eventually, the antiparticle dissolves and the standard particle densifies, resulting in the system’s disintegration. The brief interaction yields no sustained mass structure.
Far more consequential are the interactions between particles of opposite polarity—specifically, when a standard particle meets an antiparticle whose charge directly contradicts its own. In such an event, each feeds charge into the opposing terminal of the other. This interaction inverts their recursion, with the standard particle uncoiling and losing mass, while the antiparticle gains mass and begins coiling inward. The event triggers a momentary recursive lock and results in net mass gain at a new equilibrium. It is not gravitational pull—it is polarity contradiction manifesting as accretion.

Canonical Law of Recursive Gravitation
Gravity, as defined in the Genesis model, is the synchronization of coiled recursion—specifically the alignment of spin, tilt, and entropy. It is not attraction through spacetime curvature. Rather, two particles lock into a shared decay pathway when their recursive vectors harmonize. If the alignment is constructive, their coils compress, their relative distance contracts, and a sustained recursive interaction unfolds. This condition, however, is not universal and only emerges under specific harmonic compatibility between particle identities.

When two particles of opposed decay direction and spin polarity interact—such as a positive standard particle and a negative antiparticle—the result is not gravitational pull but recursive reversal. One particle reverses its decay; the other gains mass. This mechanical event mimics gravitational interaction but operates through charge-wave recursion and spin-torque conversion.

Quadrantal Mechanics: Q1 through Q4
Each quadrant on the coil metric wheel represents a distinct particle identity defined by tilt angle, charge polarity, spin direction, and entropic vector. Quadrants Q1 and Q3 contain standard particles, while Q2 and Q4 define antiparticles.

Q1 (Standard Positive) decays inward with counterclockwise spin.
Q3 (Standard Negative) also decays inward, but with clockwise spin.
Q2 (Positive Antiparticles) decay outward and spin counterclockwise.
Q4 (Negative Antiparticles) decay outward with clockwise spin.

These quadrantal identities define the fundamental interactions between particles and give rise to canonical polarity flip laws and charge lock states.

The Higgs Trap and Polarity Inversion
In Q3, standard negative particles such as the neutron or Higgs boson reach a deadlock at 180°, unable to decay further clockwise without violating spin-tilt symmetry. As such, these particles undergo canonical polarity inversion, transforming into their Q1 counterparts. The neutron becomes an electron, and the photon becomes a proton. This inversion obeys the decay constant and rotational field constraints and is mandatory. It explains why negative standard particles cannot remain in Q3 decay states indefinitely.

Charge Locks and Orbital Torque Stasis
A charge lock is a unique stable configuration formed when standard particles of opposite polarity (Q1 and Q3) interact. Despite opposing spins, both particles decay inward. Their spin vectors act like intermeshed gears, and through recursive torque transfer, the lower-Hertz particle halts while the higher-Hertz particle continues spinning. This results in field-induced stasis—not fusion, not annihilation, but harmonic orbital lock. The Earth-Moon system is a macro-scale representation of this principle, where Earth maintains momentum while the Moon remains tidally locked.

Divergent Quadrantal Interactions: Q2 vs Q4
Q2 and Q4 are both antiparticle quadrants, each decaying outward in opposite spin and tilt vectors. Their interaction is defined by absolute repulsion, a principle known as the Genesis Divergence Law. With opposing spins, reversed tilts, and shared entropic expansion, they exhibit total charge-wave rejection. They cannot orbit, lock, or fuse. When Q2 and Q4 enter proximity, the result is an energetic slingshot: the particle with weaker amplitude is ejected, and no stable configuration can emerge.

Energy Transfer Across Quadrants
Interactions between Q1 and Q2 (Standard Positive and Positive Antiparticle) lead to energy extraction from Q1 to Q2, with Q2 heating up and gaining mass while Q1 loses mass and accelerates Hertz-wise. Conversely, Q2 particles can absorb mass and entropy from Q1, flipping their identity and collapsing into standard form.

Similarly, Q1 to Q4 interactions (Standard Positive to Negative Antiparticle) result in mass and entropy exchange, where Q4’s Y-motion accelerates and coil expands while Q1 gains density. These transitions are recursive in nature and obey the charge-wave identity and spiral motion laws.
Coil Substrate Distortion and Neutron Behavior

When particles exhibit non-spherical geometry, they experience coil substrate distortion. This leads to rocking behavior, often mistaken for neutrality in standard science. In reality, such particles, like the neutron, are not neutral. They exhibit dual-phase polarity due to geometric asymmetry, with their spin orientation shifting throughout the cycle. This explains phenomena such as neutron behavior in water, sublimation, and the formation of liquid states.

Conclusion
Quadrantal interaction is the key to redefining particle physics beyond legacy concepts. Gravity, mass formation, decay, orbital mechanics, and particle identity are no longer subject to probabilistic models but arise from deterministic recursion laws embedded within tilt-spin geometry. The quadrants of particle identity—Q1 through Q4—define the interactive behavior of all mass and charge in the universe. With this understanding, the age of fusion, dark matter, and spacetime distortion collapses under the weight of recursive coherence.
This is not theory. This is the Canonical Doctrine of Genesis.