Signatures of van Hove Singularities Probed by the Supercurrent in a Graphene-hBN Superlattice

Indolese, David I.; Delagrange, R.; Makk, Péter; Wallbank, John; Wanatabe, K.; Taniguchi, Takashi; Schönenberger, Christian

doi:10.1103/physrevlett.121.137701

Cited by 26 publications

(18 citation statements)

References 58 publications

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“…Although measurements of SR in SCG have not yet been performed (which makes theoretical predictions particularly motivating), they are within the current experimental reach. Indeed, proximity induced superconductivity in graphene has been experimentally demonstrated in lateral Josephson junctions [36][37][38][39] and vertical stack geometries [40,41], as well as in alkaline-intercalated graphite [42][43][44]. The induced superconducting gap ranges from tens of μeV [36] to 1 meV [45] (T c ≃ 6.593 K).…”

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confidence: 99%

Spin Relaxation ins-Wave Superconductors in the Presence of Resonant Spin-Flip Scatterers

et al. 2020

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Employing analytical methods and quantum transport simulations we investigate the relaxation of quasiparticle spins in graphene proximitized by an s-wave superconductor in the presence of resonant magnetic and spin-orbit active impurities. Off resonance, the relaxation increases with decreasing temperature when electrons scatter off magnetic impurities-the Hebel-Slichter effect-and decreases when impurities have spin-orbit coupling. This distinct temperature dependence (not present in the normal state) uniquely discriminates between the two scattering mechanisms. However, we show that the Hebel-Slichter picture breaks down at resonances. The emergence of Yu-Shiba-Rusinov bound states within the superconducting gap redistributes the spectral weight away from magnetic resonances. The result is opposite to the Hebel-Slichter expectation: the spin relaxation decreases with decreasing temperature. Our findings hold for generic s-wave superconductors with resonant magnetic impurities, but also, as we show, for resonant magnetic Josephson junctions.

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confidence: 99%

Spin Relaxation ins-Wave Superconductors in the Presence of Resonant Spin-Flip Scatterers

et al. 2020

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“…We showed how changing the doping of the graphene layer by local gating could help correct the asymmetry in the superlattice potential induced by the charge inhomogeneity. Our results thus suggest that superconducting tunneling spectroscopy could be an interesting alternative to supercurrent measurements [52] to experimentally observe the modification of the band dispersion relation due to a superlattice potential on a graphene layer.…”

Section: Discussionmentioning

confidence: 76%

Dirac point formation revealed by Andreev tunneling in superlattice-graphene/superconductor junctions

et al. 2019

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A graphene superlattice is formed by a one-dimensional periodic potential and is characterized by the emergence of new Dirac points in the electronic structure. The group velocity of graphene's massless Dirac fermions at the new points is drastically reduced, resulting in a measurable effect in the conductance spectroscopy. We show here that tunnel spectroscopy using a superconducting hybrid junction is more sensitive to the formation of Dirac points in the spectrum of graphene superlattices due to the additional contribution of Andreev processes. We examine the transport properties of a graphene-based superlattice-superconductor hybrid junction and demonstrate that a superlattice potential can coexist with proximity-induced superconducting correlations. Both effects contribute to change graphene's spectrum for subgap energies, and as a result, the normalized tunneling conductance features sharp changes for voltages proportional to the energy separation between the original and newly generated Dirac points. Consequently, the superconducting differential conductance provides an excellent tool to reveal how the new Dirac points emerge from the original band. This result is robust against asymmetries and finite-size effects in the superlattice potential and is improved by an effective doping comparable to the superconducting gap.

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“…A milestone in graphene research is the discovery of triangular moiré patterns in the graphene/hBN heterostructure superlattice, in which the electronic properties of graphene can be tailored through periodic moiré potentials and variety of significant phenomenon have been observed, e.g. the emergence of van Hove singularities 29 , Hofstadter's butterfly 30,31 , high-temperature quantum oscillations 32 , etc. Graphene derivatives, e.g.…”

Section: ⅰⅰ Results and Discussionmentioning

confidence: 99%

Direct writing of lateral fluorographene nanopatterns with tunable bandgaps and its application in new generation of moiré superlattice

Duan

Haldar

et al. 2020

Applied Physics Reviews

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A desirable picture of graphene as an atomic thin "canvas" is to freely draw semiconducting/insulating lateral nanopatterns directly on the semi-metallic graphene surface, which is one of the most looked-for goals for monolayer device fabrications. Here, we have demonstrated a reversible electron beam activated technique, which allows to directly write semiconducting/insulating fluorographene lateral nanopatterns with tunable bandgaps on the graphene surface and a resolution down to 9-15 nm. This approach overcomes the conventional limit of semiconducting C4F in the single-sided fluorination of supported graphene and achieves insulating C2F. Moreover, by applying this technique on bilayer graphene, we have shown a new type of rectangular moiré patterns arising from the generated C2F boat/graphene superlattice for the first time. This novel technique constitutes a new approach to fabricate

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Signatures of van Hove Singularities Probed by the Supercurrent in a Graphene-hBN Superlattice

Cited by 26 publications

References 58 publications

Spin Relaxation ins-Wave Superconductors in the Presence of Resonant Spin-Flip Scatterers

Spin Relaxation ins-Wave Superconductors in the Presence of Resonant Spin-Flip Scatterers

Dirac point formation revealed by Andreev tunneling in superlattice-graphene/superconductor junctions

Direct writing of lateral fluorographene nanopatterns with tunable bandgaps and its application in new generation of moiré superlattice

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