Abstract
This paper re-examines quantum tunnelling—the penetration of a potential barrier by a subatomic particle—through the lens of classical wave dynamics. The author contends that applying the standard Schrödinger equation to this phenomenon lacks a solid physical foundation, whereas a classical wave description inherently necessitates a propagation medium. This requirement provides further evidence for a discrete, submicroscopic spatial structure: the tessellattice. By treating space as a physical substrate rather than an empty vacuum, this study identifies the source of intrinsic noise in quantum systems as inertons—mass perturbations generated by the internal dynamics of the tessellattice. While current quantum technologies rely on extreme cryogenic cooling to suppress noise, this paper argues that the abstract mathematical framework of standard quantum mechanics cannot fundamentally account for these vacuum-based fluctuations. By treating the tessellattice as a dynamic substrate, this work establishes a novel physical basis for understanding and mitigating qubit decoherence, offering a concrete, structural alternative to conventional cryogenic noise-reduction strategies.
Keywords
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