Quantum statistical model for superconducting phase in graphene and   nanotubes

Shigeji Fujita; Rohit Singh; Salvador Godoy; and Kei Ito

arXiv:0903.0701·cond-mat.supr-con·March 5, 2009

Quantum statistical model for superconducting phase in graphene and nanotubes

Shigeji Fujita, Rohit Singh, Salvador Godoy, and Kei Ito

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TL;DR

This paper introduces a quantum statistical model that explains the possibility of superconductivity at extremely high temperatures in graphene and nanotubes, aligning with experimental observations of high critical temperatures.

Contribution

It presents a novel quantum statistical theory that supports the existence of superconductivity at 1275 K in multiwalled nanotubes, providing a theoretical basis for these experimental findings.

Findings

01

Supports superconductivity at 1275 K in nanotubes

02

Provides a quantum statistical framework for high-temperature superconductivity

03

Aligns with experimental reports by Zhao and Beeli

Abstract

A quantum statistical theory is presented, supporting a superconducting state of an ultrahigh critical temperature (1275 K) in the multiwalled nanotubes reported by Zhao and Beeli [Phys. Rev. B 77, 245433 (2008)].

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Taxonomy

TopicsQuantum many-body systems · Statistical Mechanics and Entropy · Computational Physics and Python Applications