Abstract
This paper determines the possibility and plausibility of a carbon nanotube (CNT) and copper oxide perovskite cell nanocomposite that could sustain a supercurrent under higher critical parameters than either of the two materials separately. The analysis is based upon phenomenological patterns and quantitative analysis from preceding papers, including LAMH quantitative model of quasi one-dimensional superconductivity and thermally activated magnetic hysteresis. Should both CNTs and cuprate superconductors form Cooper pairs through the electron-phonon interactions and be able to condense to the same quantum state,
the correct molecular alignment of the anisotropic components will allow for a quasi one- dimensional superconducting nanocomposite as the perovskite cells are intercalated between
metallic chiral MWCNTs. This nanocomposite could possess applications in quantum computation, specifically the creation of quantum circuits through the Josephson effect.
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