Room-Temperature Superconductivity in Graphene-HBN Heterostructures: A Riemann Zeta Function-Driven Quantum Computing Paradigm

Chur Chin

Open Access Journal of Applied Science and Technology(OAJAST)

ISSN: 2993-5377 | DOI: 10.33140/OAJAST

Impact Factor: 1.08

Researchers and authors can directly submit their manuscript online through this link Online Manuscript Submission.

Track Your Submission

Share this page:

Open Access Journals

Room-Temperature Superconductivity in Graphene-HBN Heterostructures: A Riemann Zeta Function-Driven Quantum Computing Paradigm

Abstract

Chur Chin*

This paper presents a theoretical framework combining graphene-hexagonal boron nitride (hBN) heterostructures with Riemann zeta function-driven quantum state engineering to achieve superconductivity at temperatures up to 100°C (373K). Unlike conventional superconductors requiring expensive cryogenic cooling systems, our proposed architecture operates as an energy-efficient room-temperature superconductor, eliminating cooling infrastructure [1,2]. The system leverages moiré superlattice engineering, Riemann frequency pumping, exciton-polariton condensation, and Majorana fermion topological protection [3-5].

HTML PDF

Open Access Journal of Applied Science and Technology(OAJAST)

ISSN: 2993-5377 | DOI: 10.33140/OAJAST

Impact Factor: 1.08

Open Access Journal of Applied Science and Technology

Open Access Journals

Room-Temperature Superconductivity in Graphene-HBN Heterostructures: A Riemann Zeta Function-Driven Quantum Computing Paradigm

Abstract

Important Links

Locate Us