51 research outputs found
Proximity effect between two superconductors spatially resolved by scanning tunneling spectroscopy
We present a combined experimental and theoretical study of the proximity
effect in an atomic-scale controlled junction between two different
superconductors. Elaborated on a Si(111) surface, the junction comprises a Pb
nanocrystal with an energy gap of 1.2 meV, connected to a crystalline atomic
monolayer of lead with a gap of 0.23 meV. Using in situ scanning tunneling
spectroscopy we probe the local density of states of this hybrid system both in
space and in energy, at temperatures below and above the critical temperature
of the superconducting monolayer. Direct and inverse proximity effects are
revealed with high resolution. Our observations are precisely explained with
the help of a self-consistent solution of the Usadel equations. In particular,
our results demonstrate that in the vicinity of the Pb islands, the Pb
monolayer locally develops a finite proximity-induced superconducting order
parameter, well above its own bulk critical temperature. This leads to a giant
proximity effect where the superconducting correlations penetrate inside the
monolayer a distance much larger than in a non-superconducting metal.Comment: 13 pages, 14 figures, accepted for publication in Physical Review
Spectroscopic evidence for strong correlations between local superconducting gap and local Altshuler-Aronov density-of-states suppression in ultrathin NbN films
Disorder has different profound effects on superconducting thin films. For a
large variety of materials, increasing disorder reduces electronic screening
which enhances electron-electron repulsion. These fermionic effects lead to a
mechanism described by Finkelstein: when disorder combined to electron-electron
interactions increases, there is a global decrease of the superconducting
energy gap and of the critical temperature , the ratio
/ remaining roughly constant. In addition, in most films an
emergent granularity develops with increasing disorder and results in the
formation of inhomogeneous superconducting puddles. These gap inhomogeneities
are usually accompanied by the development of bosonic features: a pseudogap
develops above the critical temperature and the energy gap
starts decoupling from . Thus the mechanism(s) driving the appearance of
these gap inhomogeneities could result from a complicated interplay between
fermionic and bosonic effects. By studying the local electronic properties of a
NbN film with scanning tunneling spectroscopy (STS) we show that the
inhomogeneous spatial distribution of is locally strongly correlated
to a large depletion in the local density of states (LDOS) around the Fermi
level, associated to the Altshuler-Aronov effect induced by strong electronic
interactions. By modelling quantitatively the measured LDOS suppression, we
show that the latter can be interpreted as local variations of the film
resistivity. This local change in resistivity leads to a local variation of
through a local Finkelstein mechanism. Our analysis furnishes a purely
fermionic scenario explaining quantitatively the emergent superconducting
inhomogeneities, while the precise origin of the latter remained unclear up to
now.Comment: 11 pages, 4 figure
Self-ordered nanoporous lattice formed by chlorine atoms on Au(111)
A self-ordered nanoporous lattice formed by individual chlorine atoms on the Au(111) surface has been studied with low-temperature scanning tunneling microscopy, low-energy electron diffraction, and density functional theory calculations. We have found out that room-temperature adsorption of 0.09–0.30 monolayers of chlorine on Au(111) followed by cooling below 110 K results in the spontaneous formation of a nanoporous quasihexagonal structure with a periodicity of 25–38 Å depending on the initial chlorine coverage. The driving force of the superstructure formation is attributed to the substrate-mediated elastic interaction
Scanning tunneling spectroscopy study of the proximity effect in a disordered two-dimensional metal
The proximity effect between a superconductor and a highly diffusive two-dimensional metal is revealed in a scanning tunneling spectroscopy experiment. The in situ elaborated samples consist of superconducting single crystalline Pb islands interconnected by a nonsuperconducting atomically thin disordered Pb wetting layer. In the vicinity of each superconducting island the wetting layer acquires specific tunneling characteristics which reflect the interplay between the proximity-induced superconductivity and the inherent electron correlations of this ultimate diffusive two-dimensional metal. The observed spatial evolution of the tunneling spectra is accounted for theoretically by combining the Usadel equations with the theory of dynamical Coulomb blockade; the relevant length and energy scales are extracted and found in agreement with available experimental dataWe thank Hermann Grabert for useful discussions. This work was supported by grants from the University Pierre et Marie Curie (UPMC) ‘‘Emergence’’ and by CNRS Ph.D. Grant (L. S.-G.). J. C. C. and F. S. B. acknowledge financial support from the Spanish MICINN (Contracts No. FIS2011-28851-C02-01 and No. FIS2011-28851- C02-02
Shaping graphene superconductivity with nanometer precision
Graphene holds great potential for superconductivity due to its pure
two-dimensional nature, the ability to tune its carrier density through
electrostatic gating, and its unique, relativistic-like electronic properties.
At present, we are still far from controlling and understanding graphene
superconductivity, mainly because the selective introduction of superconducting
properties to graphene is experimentally very challenging. Here, we have
developed a method that enables shaping at will graphene superconductivity
through a precise control of graphene-superconductor junctions. The method
combines the proximity effect with scanning tunnelling microscope (STM)
manipulation capabilities. We first grow Pb nano-islands that locally induce
superconductivity in graphene. Using a STM, Pb nano-islands can be selectively
displaced, over different types of graphene surfaces, with nanometre scale
precision, in any direction, over distances of hundreds of nanometres. This
opens an exciting playground where a large number of predefined
graphene-superconductor hybrid structures can be investigated with atomic scale
precision. To illustrate the potential, we perform a series of experiments,
rationalized by the quasi-classical theory of superconductivity, going from the
fundamental understanding of superconductor-graphene-superconductor
heterostructures to the construction of superconductor nanocorrals, further
used as "portable" experimental probes of local magnetic moments in graphene
On the importance of measuring accurately LDOS maps using scanning tunneling spectroscopy in materials presenting atom-dependent charge order: the case of the correlated Pb/Si(111) single atomic layer
We show how to properly extract the local charge order in two-dimensional
materials from scanning tunneling microscopy/spectroscopy (STM/STS)
measurements. When the charge order presents spatial variations at the atomic
scale inside the unit cell and is energy dependent, particular care should be
taken. In such cases the use of the lock-in technique, while acquiring an STM
topography in closed feedback loop, leads to systematically incorrect dI/dV
measurements giving a false local charge order. A correct method is either to
perform a constant height measurement or to perform a full grid of dI/dV(V)
spectroscopies, using a bias voltage setpoint outside the material bandwidth
where the local density-of-states (LDOS) is spatially homogeneous. We take as a
paradigmatic example of two-dimensional material the 1/3 single-layer
Pb/Si(111). As large areas of this phase cannot be grown, charge ordering in
this system is not accessible to angular resolved photoemission or grazing
x-ray diffraction. Previous investigations by STM/STS supplemented by {\it ab
initio} Density Functional Theory (DFT) calculations concluded that this
material undergoes a phase transition to a low-temperature
reconstruction where one Pb atom moves up, the two remaining Pb atoms shifting
down. A third STM/STS study by Adler {\it et al.} [PRL 123, 086401 (2019)] came
to the opposite conclusion, i.e. that two Pb atoms move up, while one Pb atom
shifts down. This latter erroneous conclusion comes from a misuse of the
lock-in technique. In contrast, using a full grid of dI/dV(V) spectroscopy
measurements, we show that the energy-dependent LDOS maps agree very well with
state-of-the-art DFT calculations confirming the one-up two-down charge
ordering. This structural and charge re-ordering in the unit cell
is equally driven by electron-electron interactions and the coupling to the
substrate.Comment: 11 pages, 3 figure
Weakly Trapped, Charged, and Free Excitons in Single-Layer MoS2 in the Presence of Defects, Strain, and Charged Impurities
Few- and single-layer MoS2 host substantial densities of defects. They are thought to influence the doping level, the crystal structure, and the binding of electron-hole pairs. We disentangle the concomitant spectroscopic expression of all three effects and identify to what extent they are intrinsic to the material or extrinsic to it, i.e., related to its local environment. We do so by using different sources of MoS2 - a natural one and one prepared at high pressure and high temperature - and different substrates bringing varying amounts of charged impurities and by separating the contributions of internal strain and doping in Raman spectra. Photoluminescence unveils various optically active excitonic complexes. We discover a defect-bound state having a low binding energy of 20 meV that does not appear sensitive to strain and doping, unlike charged excitons. Conversely, the defect does not significantly dope or strain MoS2. Scanning tunneling microscopy and density functional theory simulations point to substitutional atoms, presumably individual nitrogen atoms at the sulfur site. Our work shows the way to a systematic understanding of the effect of external and internal fields on the optical properties of two-dimensional materials
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