Freestanding single-crystal superconducting electron-doped cuprate membrane

S. Sandik; Bat Chen Elshalem; A. Azulay; M. Waisbort; A. Kohn; B. Kalisky; Y. Dagan

doi:10.1103/PhysRevMaterials.9.L021802

Freestanding single-crystal superconducting electron-doped cuprate membrane

S. Sandik, Bat Chen Elshalem, A. Azulay, M. Waisbort, A. Kohn, B. Kalisky, Y. Dagan

Tel Aviv University, Bar-Ilan University

Research output: Contribution to journal › Article › peer-review

Abstract

Thin films of cuprate superconductors are easier to control in terms of doping as compared to bulk samples. However, they require specific substrates to facilitate epitaxial growth. These substrates are often incompatible with materials used in electronic applications. Furthermore, it is challenging to separate the substrate's properties from the material of interest. Here, we demonstrate the fabrication of an electron-doped cuprate membrane. We show that the membrane has a coherent crystal structure. Furthermore, the superconducting properties of the membrane postliftoff closely resemble those of the thin films preliftoff, as revealed by a scanning superconducting quantum interference device (SQUID) microscope. Such membranes pave the way for designing new material properties and incorporating complex superconducting materials into typically incompatible electronic devices.

Original language	English
Article number	L021802
Number of pages	4
Journal	Physical Review Materials
Volume	9
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevMaterials.9.L021802
State	Published - 27 Feb 2025

All Science Journal Classification (ASJC) codes

General Materials Science
Physics and Astronomy (miscellaneous)

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10.1103/PhysRevMaterials.9.L021802

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title = "Freestanding single-crystal superconducting electron-doped cuprate membrane",

abstract = "Thin films of cuprate superconductors are easier to control in terms of doping as compared to bulk samples. However, they require specific substrates to facilitate epitaxial growth. These substrates are often incompatible with materials used in electronic applications. Furthermore, it is challenging to separate the substrate's properties from the material of interest. Here, we demonstrate the fabrication of an electron-doped cuprate membrane. We show that the membrane has a coherent crystal structure. Furthermore, the superconducting properties of the membrane postliftoff closely resemble those of the thin films preliftoff, as revealed by a scanning superconducting quantum interference device (SQUID) microscope. Such membranes pave the way for designing new material properties and incorporating complex superconducting materials into typically incompatible electronic devices.",

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AU - Sandik, S.

AU - Elshalem, Bat Chen

AU - Azulay, A.

AU - Waisbort, M.

AU - Kohn, A.

AU - Kalisky, B.

AU - Dagan, Y.

PY - 2025/2/27

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N2 - Thin films of cuprate superconductors are easier to control in terms of doping as compared to bulk samples. However, they require specific substrates to facilitate epitaxial growth. These substrates are often incompatible with materials used in electronic applications. Furthermore, it is challenging to separate the substrate's properties from the material of interest. Here, we demonstrate the fabrication of an electron-doped cuprate membrane. We show that the membrane has a coherent crystal structure. Furthermore, the superconducting properties of the membrane postliftoff closely resemble those of the thin films preliftoff, as revealed by a scanning superconducting quantum interference device (SQUID) microscope. Such membranes pave the way for designing new material properties and incorporating complex superconducting materials into typically incompatible electronic devices.

AB - Thin films of cuprate superconductors are easier to control in terms of doping as compared to bulk samples. However, they require specific substrates to facilitate epitaxial growth. These substrates are often incompatible with materials used in electronic applications. Furthermore, it is challenging to separate the substrate's properties from the material of interest. Here, we demonstrate the fabrication of an electron-doped cuprate membrane. We show that the membrane has a coherent crystal structure. Furthermore, the superconducting properties of the membrane postliftoff closely resemble those of the thin films preliftoff, as revealed by a scanning superconducting quantum interference device (SQUID) microscope. Such membranes pave the way for designing new material properties and incorporating complex superconducting materials into typically incompatible electronic devices.

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Freestanding single-crystal superconducting electron-doped cuprate membrane

Abstract

All Science Journal Classification (ASJC) codes

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