A New Model of Quantum Transport

 

A New Model of Quantum Transport

Abstract

This paper proposes a novel model for particle motion that challenges conventional interpretations of wave-particle duality and continuous spacetime propagation. In this framework, the photon is not a classical wave nor a particle in motion, but a quantum excitation that propagates via a discrete sequence of local field interactions. These interactions—consisting of annihilation, phase cancellation, and recombination—occur stepwise through the vacuum, with the speed of light governed by the rate at which these processes can occur. This mechanism is likened to a form of "warp drive," not in the relativistic sense of spacetime distortion, but as a continual reconstruction of the particle state just ahead of its prior location.

The model is extended to include fermions, whose propagation arises from similar recombination dynamics, determined by the rate of interaction between the Higgs field and other fundamental fields. This approach offers a coherent means of deriving speed, frequency, and wavelength from fundamental interaction rates, suggesting that all motion is a product of field synchronization delays rather than classical inertia or trajectory.

Implications for special relativity are discussed, particularly with regard to time dilation and relativistic mass increase as emergent phenomena from delayed field recombination. The paper concludes with a speculative outlook on the feasibility of engineered matter transmission—analogous to a "transporter beam"—based on controlling the annihilation and recombination of field states in a targeted fashion.

---

1. Introduction

Conventional physics describes the photon as both a wave and a particle, governed by Maxwell's equations and quantum field theory. However, the transition between these perspectives remains conceptually opaque. This paper explores an alternative view: that photons, and by extension all particles, propagate not by movement through space, but by successive local interactions that reconstruct their presence ahead of each prior position.

This process, resembling a field-based "warp drive," eliminates the need for a continuous trajectory or inertia. Instead, it emphasizes the underlying mechanisms of field interaction, particularly the finite delay inherent in the vacuum's permittivity and permeability, and for fermions, their coupling to the Higgs field.

2. The Photon as a Reconstructive Pulse

Rather than flowing like a wave or shooting like a bullet, the photon is treated here as a self-sustaining excitation that undergoes localized cancellation and regeneration. The electric and magnetic fields alternately peak and cancel, and the resulting energy is transferred forward by field-induced recombination. Each recombination event re-establishes the photon's structure in a new spatial position. This chain of events propagates the photon at a maximum rate defined by the vacuum's reactive properties, i.e., the speed of light.

3. Extension to Fermions

Fermions, unlike photons, possess mass due to their interaction with the Higgs field. In this model, their propagation also follows a recombination pathway, but at a rate limited by the time required for the Higgs field to restore the particle's mass properties during each phase cycle. As a result, fermions exhibit slower movement compared to massless bosons, and their frequency and wavelength arise from the specific timing of these reconstructive events.

4. Implications for Relativity

Special relativity attributes phenomena such as time dilation and mass increase to high-velocity motion through spacetime. In the proposed model, these effects emerge naturally from the increased duration required for field recombination events as a particle's energy increases. Thus, relativistic limits are not imposed externally but arise intrinsically from the field interaction mechanisms themselves.

5. Future Directions: The Transporter Beam

The analogy to the Star Trek transporter is more than poetic. If particles are indeed patterns of recurring field recombination, then matter transmission could, in principle, be achieved by controlling these recombination events remotely. While currently speculative, this approach suggests a new path for quantum teleportation or matter replication technologies that operate by inducing and guiding phase transitions across space.

6. Conclusion

This field-based model of particle propagation presents a unified mechanism by which both photons and fermions traverse space, not by travel but by transformation. By grounding motion in discrete, local field interactions, this framework provides fresh insight into the nature of energy, mass, and spacetime. It invites reconsideration of longstanding assumptions and opens new avenues for theoretical and applied physics.