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Yoshizawa, Shunsuke; Kim, Howon; Kawakami, Takuto; Nagai, Yuki; Nakayama, Tomonobu; Hu, Xiao; Hasegawa, Yukio; Uchihashi, Takashi

doi:10.1103/physrevlett.113.247004

Cited by 75 publications

(61 citation statements)

References 35 publications

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“…Among these reconstructions, the √7 × √3 has attracted much interest recently, because it shows a free-electron-like two dimensional metallic state [12,13] and superconductivity at about 3 K [14][15][16][17][18]. It is reported that two phases of the √7 × √3 reconstruction exist, which show slightly different appearances in scanning tunneling microscopy (STM) images, from which they derive their names: a hexagonal and a rectangular phase (denoted as "hex" and "rect", hereafter).…”

Section: Introductionmentioning

confidence: 99%

Indium coverage of the Si(111)- 7×3 -In surface

et al. 2017

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The Indium coverage of the Si(111)-√7 × √3-In surface is investigated by means of X-ray photoelectron spectroscopy and first-principles density functional theory calculations. Both experimental and theoretical results indicate that the In coverage is rather a double layer than a single layer. Moreover, the atomic structure of the Si(111)-√7 × √3-In surface is discussed by comparing experimental with simulated scanning tunneling microscopy (STM) images and scanning tunneling spectra with the calculated density of states. Our structural assignment agrees with previous studies except for the interpretation of experimental STM images.

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Section: Introductionmentioning

confidence: 99%

Indium coverage of the Si(111)- 7×3 -In surface

et al. 2017

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“…Our results indicate that the atomic steps work as Josephson junctions and allow supercurrents to flow with a limited rate. Detailed results, discussions and theoretical calculations are presented elsewhere [9,10].…”

Section: Introductionmentioning

confidence: 99%

Impact of Surface Conditions on the Superconductivity of Si(111)-(√7 × √3)-In

Yoshizawa

Kim

Kawakami

et al. 2015

e-J. Surf. Sci. Nanotech.

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We performed low-temperature scanning tunneling microscopy and spectroscopy on Si(111)-( √ 7× √ 3)-In in magnetic fields. Superconducting vortices were observed by mapping zero-bias conductance in an area consisting of flat terraces separated by atomic steps. While vortices in the terrace regions have an isotropic shape with a normal-state core, those at the atomic steps have anisotropic shapes and the superconductivity is only weakly suppressed in the cores. These properties are understood as a crossover from a normal vortex to a Josephson vortex. We conclude that the atomic steps work as Josephson junctions limiting the density of supercurrents.

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“…In addition, impurities locally suppress superconductivity, which in superconducting nanowires can promote a phase slip center, giving rise to the broad temperature transition and residual resistance 25,26 . Very recently, a step in atomically thin films was found to have a strong effect on electronic transport 27,28 and vortex matter 24,29,30 , as a new paradigm in the interplay between the local defects and low-dimensional superconductivity. As an extended defect, the step does not only scatter electrons (leading to the modification on the overall electronic structure of the sample 31 ), but also affects the flow of superconduct-ing currents and the proximity-induced superconducting correlations 27,28 .…”

Section: Introductionmentioning

confidence: 99%

Superconducting nanoribbon with a constriction: A quantum-confined Josephson junction

et al. 2018

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Extended defects are known to strongly affect nanoscale superconductors. Here we report the properties of superconducting nanoribbons with a constriction formed between two adjacent stepedges, by solving the Bogoliubov-de Gennes equations self-consistently in the regime where quantum confinement is important. Since the quantum resonances of the superconducting gap in the constricted area are different from the rest of the nanoribbon, such constriction forms a quantumconfined S-S'-S Josephson junction, with a broadly tunable performance depending on the length and width of the constriction with respect to the nanoribbon, and possible gating. These findings provide an intriguing approach to further tailor superconducting quantum devices where Josephson effect is of use.

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Imaging Josephson Vortices on the Surface SuperconductorSi(111)−(7×3)

Cited by 75 publications

References 35 publications

Indium coverage of the Si(111)- 7×3 -In surface

Indium coverage of the Si(111)- 7×3 -In surface

Impact of Surface Conditions on the Superconductivity of Si(111)-(√7 × √3)-In

Superconducting nanoribbon with a constriction: A quantum-confined Josephson junction

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Imaging Josephson Vortices on the Surface SuperconductorSi(111)−(7×3)

Cited by 75 publications

References 35 publications

Indium coverage of the Si(111)- 7×3 -In surface

Indium coverage of the Si(111)- 7×3 -In surface

Impact of Surface Conditions on the Superconductivity of Si(111)-(&radic;7 &times; &radic;3)-In

Superconducting nanoribbon with a constriction: A quantum-confined Josephson junction

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Impact of Surface Conditions on the Superconductivity of Si(111)-(√7 × √3)-In