High magnetic field response of superconductivity dome in quantum artificial High Tc superlattices with variable geometry

• URL: http://arxiv.org/abs/2512.11494v1
• Date: Fri, 12 Dec 2025 11:42:35 GMT
• Title: High magnetic field response of superconductivity dome in quantum artificial High Tc superlattices with variable geometry
• Authors: Gaetano Campi, Andrea Alimenti, Sang-Eon Lee, Luis Balicas, Fedor F. Balakirev, G. Alexander Smith, Gennady Logvenov, Antonio Bianconi,
• Abstract summary: We report high-field magneto transport measurements up to 41 Tesla of AHTS across the entire superconducting dome.<n>The measured superconducting coherence length demonstrates that atomic-scale engineering controls not only the critical temperature but also the intrinsic pair size at Fano-Feshbach resonances physics.
• Score: 0.731365367571807
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: It is known that cuprate artificial high temperature superlattices (AHTS) with period d, composed of quantum wells confining interface space charge in stoichiometric Mott insulator layers (S), with thickness L, at the interface with overdoped normal metallic cuprate layers (N) show a superconducting dome by tuning the geometric L over d ratio of the SNSN superlattice with the top predicted by quantum material design engineering quantum size effects. Here we report high-field magneto transport measurements up to 41 Tesla of AHTS across the entire superconducting dome. The results show the universal upward-concave behavior of the temperature dependent upper critical magnetic field in low critical temperature samples at rising edge and drop edge of the dome providing compelling evidence for two-band superconductivity in agreement with multigap theory used for quantum design of the SNSN superlattices. The measured superconducting coherence length demonstrates that atomic-scale engineering controls not only the critical temperature but also the intrinsic pair size at Fano-Feshbach resonances physics paving the way toward next generation quantum devices and shedding light on unconventional superconductivity.

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