Simultaneous Enhancement of Electrical and Thermal Conductivity in Graphene through Excitation of the Etheric Longitudinal Mode presents a clear and experimentally testable prediction within the Quarkbase Cosmology framework: the resonant excitation of the etheric longitudinal mode in graphene (10–60 THz) produces a simultaneous and correlated enhancement of both electrical conductivity (σ) and thermal conductivity (κ). In this model, charge and heat transport are not governed solely by electron and phonon scattering, but by their coupling to the scalar pressure field Ψ(x,t) of the etheric plasma. When an external THz or mid-infrared excitation matches the natural resonance ωΨ of the confined longitudinal mode in graphene, the scattering rates decrease in parallel for electrical and thermal carriers, increasing the relaxation times τe and τq. Both σ and κ acquire the same Lorentzian resonance profile, centered at ωΨ, with the correlation between their enhancements approaching unity (r ≈ 1). Expected relative increases are: Δσ/σ ≈ 0.5–3% Δκ/κ ≈ 0.5–2% These values exceed the detection thresholds of standard four-probe electrical measurements and time-domain thermoreflectance, enabling a direct and feasible experimental verification. Observation of this paired response would constitute clear evidence that the etheric longitudinal mode acts as a unified transport channel—supporting the Quarkbase description of the vacuum as a frictionless pressure medium underlying electromagnetic and thermal phenomena.
Date: Nov 25, 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/17717055
- https://archive.org/details/simultaneous-enhancement-of-electrical-and-thermal-conductivity-in-graphene-thro
- https://www.academia.edu/145254169/Simultaneous_Enhancement_of_Electrical_and_Thermal_Conductivity_in_Graphene_through_Excitation_of_the_Etheric_Longitudinal_Mode