Nanoscale superconducting states in the fe-based filamentary superconductor of pr-doped cafe2 as2

Giang D. Nguyen; Mingming Fu; Qiang Zou; Liurukara D. Sanjeewa; An Ping Li; Athena S. Sefat; Zheng Gai

doi:10.3390/nano11041019

Nanoscale superconducting states in the fe-based filamentary superconductor of pr-doped cafe₂ as₂

Giang D. Nguyen, Mingming Fu, Qiang Zou, Liurukara D. Sanjeewa, An Ping Li, Athena S. Sefat, Zheng Gai

Scanning Tunneling Microscopy Group

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

3 Scopus citations

Abstract

The low-temperature scanning tunneling microscope and spectroscopy (STM/STS) are used to visualize superconducting states in the cleaved single crystal of 9% praseodymium-doped CaFe₂ As₂ (Pr-Ca122) with T_c ≈ 30 K. The spectroscopy shows strong spatial variations in the density of states (DOS), and the superconducting map constructed from spectroscopy discloses a localized superconducting phase, as small as a single unit cell. The comparison of the spectra taken at 4.2 K and 22 K (below vs. close to the bulk superconducting transition temperature) from the exact same area confirms the superconducting behavior. Nanoscale superconducting states have been found near Pr dopants, which can be identified using dI/dV conductance maps at +300 mV. There is no correlation of the local superconductivity to the surface reconstruction domain and surface defects, which reflects its intrinsic bulk behavior. We, therefore, suggest that the local strain of Pr dopants is competing with defects induced local magnetic moments; this competition is responsible for the local superconducting states observed in this Fe-based filamentary superconductor.

Original language	English
Article number	1019
Journal	Nanomaterials
Volume	11
Issue number	4
DOIs	https://doi.org/10.3390/nano11041019
State	Published - Apr 2021

Funding

Acknowledgments: This research was conducted at the Center for Nanophase Materials Sciences, which is a DOE Office of Science User Facility. G.D.N., L.D.S., A.S.S. and part of Z.G.’s research in this work was supported by the U.S. Department of Energy (DOE), Office of Science, Basic Energy Sciences (BES), Materials Science and Engineering (MSE) Division.

Keywords

Defects
Defects
Domain boundary
Filamentary superconductor
Iron-based superconductor
Nanoscale superconducting states
Scanning probe microscopy

Access to Document

10.3390/nano11041019

Cite this

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title = "Nanoscale superconducting states in the fe-based filamentary superconductor of pr-doped cafe2 as2",

abstract = "The low-temperature scanning tunneling microscope and spectroscopy (STM/STS) are used to visualize superconducting states in the cleaved single crystal of 9% praseodymium-doped CaFe2 As2 (Pr-Ca122) with Tc ≈ 30 K. The spectroscopy shows strong spatial variations in the density of states (DOS), and the superconducting map constructed from spectroscopy discloses a localized superconducting phase, as small as a single unit cell. The comparison of the spectra taken at 4.2 K and 22 K (below vs. close to the bulk superconducting transition temperature) from the exact same area confirms the superconducting behavior. Nanoscale superconducting states have been found near Pr dopants, which can be identified using dI/dV conductance maps at +300 mV. There is no correlation of the local superconductivity to the surface reconstruction domain and surface defects, which reflects its intrinsic bulk behavior. We, therefore, suggest that the local strain of Pr dopants is competing with defects induced local magnetic moments; this competition is responsible for the local superconducting states observed in this Fe-based filamentary superconductor.",

keywords = "Defects, Defects, Domain boundary, Filamentary superconductor, Iron-based superconductor, Nanoscale superconducting states, Scanning probe microscopy",

author = "Nguyen, {Giang D.} and Mingming Fu and Qiang Zou and Sanjeewa, {Liurukara D.} and Li, {An Ping} and Sefat, {Athena S.} and Zheng Gai",

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T1 - Nanoscale superconducting states in the fe-based filamentary superconductor of pr-doped cafe2 as2

AU - Nguyen, Giang D.

AU - Fu, Mingming

AU - Zou, Qiang

AU - Sanjeewa, Liurukara D.

AU - Li, An Ping

AU - Sefat, Athena S.

AU - Gai, Zheng

PY - 2021/4

Y1 - 2021/4

N2 - The low-temperature scanning tunneling microscope and spectroscopy (STM/STS) are used to visualize superconducting states in the cleaved single crystal of 9% praseodymium-doped CaFe2 As2 (Pr-Ca122) with Tc ≈ 30 K. The spectroscopy shows strong spatial variations in the density of states (DOS), and the superconducting map constructed from spectroscopy discloses a localized superconducting phase, as small as a single unit cell. The comparison of the spectra taken at 4.2 K and 22 K (below vs. close to the bulk superconducting transition temperature) from the exact same area confirms the superconducting behavior. Nanoscale superconducting states have been found near Pr dopants, which can be identified using dI/dV conductance maps at +300 mV. There is no correlation of the local superconductivity to the surface reconstruction domain and surface defects, which reflects its intrinsic bulk behavior. We, therefore, suggest that the local strain of Pr dopants is competing with defects induced local magnetic moments; this competition is responsible for the local superconducting states observed in this Fe-based filamentary superconductor.

AB - The low-temperature scanning tunneling microscope and spectroscopy (STM/STS) are used to visualize superconducting states in the cleaved single crystal of 9% praseodymium-doped CaFe2 As2 (Pr-Ca122) with Tc ≈ 30 K. The spectroscopy shows strong spatial variations in the density of states (DOS), and the superconducting map constructed from spectroscopy discloses a localized superconducting phase, as small as a single unit cell. The comparison of the spectra taken at 4.2 K and 22 K (below vs. close to the bulk superconducting transition temperature) from the exact same area confirms the superconducting behavior. Nanoscale superconducting states have been found near Pr dopants, which can be identified using dI/dV conductance maps at +300 mV. There is no correlation of the local superconductivity to the surface reconstruction domain and surface defects, which reflects its intrinsic bulk behavior. We, therefore, suggest that the local strain of Pr dopants is competing with defects induced local magnetic moments; this competition is responsible for the local superconducting states observed in this Fe-based filamentary superconductor.

KW - Defects

KW - Domain boundary

KW - Filamentary superconductor

KW - Iron-based superconductor

KW - Nanoscale superconducting states

KW - Scanning probe microscopy

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