Quantum Vacuum Induced Macroscopic Coherence in Quantum Materials

TL;DR

This paper proposes a unified theoretical framework linking quantum vacuum effects, causal set theory, and holographic duality to explain macroscopic coherence and high-temperature superconductivity in quantum materials.

Contribution

It introduces a novel interdisciplinary approach combining quantum electrodynamics, causal set theory, and holography to explain macroscopic quantum coherence and superconductivity.

Findings

Quantum vacuum can induce macroscopic coherence in materials.

Causal set theory characterizes nonlocal correlations and horizon effects.

Holographic duality relates electronic structure to higher-dimensional gravitational systems.

Abstract

This paper, based on the interdisciplinary frontiers of quantum electrodynamics, causal set theory, and the AdS/CFT holographic duality, integrates Keppler's zero point field resonance theory, the discrete causal structure and horizon thermodynamics within causal set theory, and the latest advancements in holographic superconductivity models. For the first time, we establish a unified dynamical framework for macroscopic coherent states in quantum materials. We demonstrate that: (1) The quantum vacuum can form macroscopic coherent states with specific molecular electronic states in materials through resonant coupling, corresponding to a new mechanism for superconducting pairing; (2) The partial order relations and strongly connected components in causal set theory characterize the nonlocal correlation topology among quantum systems, with black hole event horizons exhibiting a blocking effect on such correlations; (3) Holographic duality treats the electronic structure of materials as a projection of a higher dimensional gravitational system onto the boundary, where the coherence length of the projection kernel satisfies a universal scaling law. Based on this, we deduce three groundbreaking discoveries: High Temperature Superconducting Pairing Mechanism Induced by Zero Point Field Resonance, Superconducting Synergy and Horizon Blocking in Causal Structure Networks, and Quantum Material Phase Transition Control Driven by Holographic Projection. Each discovery is translated into explicit experimental protocols and falsifiable conditions, and is compared and analyzed against mainstream experimental observations in the field of high temperature superconductivity, opening a computable and testable new direction for understanding emergent phenomena in quantum materials.