Superconductivity and Thermal Hyperconductivity in Graphene from Quarkbase Cosmology develops a unified mechanism for superconductivity and thermal hyperconductivity in graphene within the framework of Quarkbase Cosmology. In this model, the vacuum is a frictionless etheric plasma described by a pressure field Ψ(x, t), and graphene acts as a two-dimensional resonant cavity that forces Ψ into coherent phase states. The paper derives an effective Ginzburg–Landau formulation for the collective Ψ-phase, predicts dissipationless electric currents without Cooper pairing, and shows how the same coherent dynamics account for graphene’s extreme thermal conductivity (>5000 W/m·K). A quantitative BKT analysis yields realistic Tc values (1–10 K), matching experimental data from pristine and twisted-bilayer graphene. The study provides multiple falsifiable predictions involving strain dependence, dielectric environment, resonant excitation, phase interferometry, and correlated variations of Tc and κ. It positions graphene as a direct macroscopic probe of the etheric pressure field and presents a coherent field-theoretic explanation for both its electrical and thermal anomalies
Date: Nov 09, 2025
Author: Carlos Omeñaca Prado
ORCID: https://orcid.org/0009-0001-9750-5827
Resource type: Preprint
Publisher: Zenodo
License: CC BY-SA 4.0 International
Related links:
- https://zenodo.org/records/17717264
- https://archive.org/details/the-quarkbase-cosmology-explanation-of-superconductivity-and-thermal-hyperconductivity-in-graphene
- https://www.academia.edu/145253654/The_Quarkbase_Cosmology_Explanation_of_Superconductivity_and_Thermal_Hyperconductivity_in_Graphene