117,821 research outputs found
Gr\"obner bases and syzygies on bimodules
We propose a new more efficient method for the computation of two-sided
Gr\"obner bases of ideals and bimodules shifting the problem to the enveloping
algebra. Arising from the ideas this method involves, we introduce the notion
of two-sided syzygy, which reveals to be useful in the computation of the
intersection of bimodules. Further applications are left for a sequel.Comment: 14 pages, 4 algorithms, submitted to J. Symb. Compu
Understanding and enhancing superconductivity in FeSe/STO by quantum size effects
Superconductivity in one-atom-layer iron selenide (FeSe) on a strontium
titanate (STO) substrate is enhanced by almost an order of magnitude with
respect to bulk FeSe. There is recent experimental evidence suggesting that
this enhancement persists in FeSe/STO nano-islands. More specifically, for
sizes nm, the superconducting gap is a highly non-monotonic
function of with peaks well above the bulk gap value. This is the expected
behavior only for weakly-coupled metallic superconductors such as Al or Sn.
Here we develop a theoretical formalism to describe these experiments based on
three ingredients: Eliashberg theory of superconductivity in the weak coupling
limit, pairing dominated by forward scattering and periodic orbit theory to
model spectral fluctuations. We obtain an explicit analytical expression for
the size dependence of the gap that describes quantitatively the experimental
results with no free parameters. This is a strong suggestion that
superconductivity in FeSe/STO is mediated by STO phonons. We propose that,
since FeSe/STO is still a weakly coupled superconductor, quantum size effects
can be used to further enhance the bulk critical temperature in this interface.Comment: 20 pages, 2 figures, added references and corrected typo
Interplay of classical and "quantum" capacitance in a one dimensional array of Josephson junctions
Even in the absence of Coulomb interactions phase fluctuations induced by
quantum size effects become increasingly important in superconducting
nano-structures as the mean level spacing becomes comparable with the bulk
superconducting gap. Here we study the role of these fluctuations, termed
"quantum capacitance", in the phase diagram of a one-dimensional (1D) ring of
ultrasmall Josephson junctions (JJ) at zero temperature by using path integral
techniques. Our analysis also includes dissipation due to quasiparticle
tunneling and Coulomb interactions through a finite mutual and self
capacitance. The resulting phase diagram has several interesting features: A
finite quantum capacitance can stabilize superconductivity even in the limit of
only a finite mutual-capacitance energy which classically leads to breaking of
phase coherence. In the case of vanishing charging effects, relevant in cold
atom settings where Coulomb interactions are absent, we show analytically that
superfluidity is robust to small quantum finite-size fluctuations and identify
the minimum grain size for phase coherence to exist in the array. We have also
found that the renormalization group results are in some cases very sensitive
to relatively small changes of the instanton fugacity. For instance, a certain
combination of capacitances could lead to a non-monotonic dependence of the
superconductor-insulator transition on the Josephson coupling.Comment: 11 pages, 4 figure
Number theory, periodic orbits and superconductivity in nano-cubes
We study superconductivity in isolated superconducting nano-cubes and
nano-squares of size in the limit of negligible disorder, and for which mean-field theory and semiclassical
techniques are applicable, with the Fermi wave vector, the mean
level spacing and the bulk gap. By using periodic orbit theory and
number theory we find explicit analytical expressions for the size dependence
of the superconducting order parameter. Our formalism takes into account
contributions from both the spectral density and the interaction matrix
elements in a basis of one-body eigenstates. The leading size dependence of the
energy gap in three dimensions seems to be universal as it agrees with the
result for chaotic grains. In the region of parameters corresponding to
conventional metallic superconductors, and for sizes nm, the
contribution to the superconducting gap from the matrix elements is substantial
(). Deviations from the bulk limit are still clearly observed even
for comparatively large grains nm. These analytical results are in
excellent agreement with the numerical solution of the mean-field gap equation.Comment: 10 pages, 3 figures, 2 appendice
Strong enhancement of bulk superconductivity by engineered nanogranularity
It is now well established, both theoretically and experimentally, that very
small changes in the size of isolated nanograins lead to substantial
nonmonotonic variations, and sometimes enhancement, of the mean-field
spectroscopic gap of conventional superconductors. A natural question to ask,
of broad relevance for the theory and applications of superconductivity, is
whether these size effects can also enhance the critical temperature of a bulk
granular material composed of such nanograins. Here we answer this question
affirmatively. We combine mean-field, semiclassical, and percolation techniques
to show that engineered nanoscale granularity in conventional superconductors
can enhance the critical temperature by up to a few times compared to the
nongranular bulk limit. This prediction is valid for three-dimensional and also
quasi-two-dimensional samples, provided the thickness is much larger than the
grain size. Our model takes into account an experimentally realistic
distribution of grain sizes in the array, charging effects, tunnelling by
quasiparticles, and limitations related to the proliferation of thermal
fluctuations for sufficiently small grains.Comment: 11 pages, 5 figure
Universal quantum constraints on the butterfly effect
Lyapunov exponents, a purely classical quantity, play an important role in
the evolution of quantum chaotic systems in the semiclassical limit. We
conjecture the existence of an upper bound on the Lyapunov exponents that
contribute to the quantum motion, namely, even in the semiclassical limit only
a limited range of Lyapunov exponents, bounded from above, are important for
the quantum evolution. This is a universal feature in any quantum system or
quantum field theory, including those with a gravity dual. It has its origin in
the finite size of the Hilbert space that is available to an initial
quasi-classical configuration. An upper bound also exists in the limit of an
infinite Hilbert space provided that the system is in contact with an
environment, for instance a thermal bath. An important consequence of this
result is a universal quantum bound on the maximum growth rate of the
entanglement entropy at zero and finite temperature.Comment: 5 page
Phase coherence in one-dimensional superconductivity by power-law hopping
In a one-dimensional (1D) superconductor, zero temperature quantum
fluctuations destroy phase coherence. Here we put forward a mechanism which can
restore phase coherence: power-law hopping. We study a 1D attractive-U Hubbard
model with power-law hopping by Abelian bosonization and density-matrix
renormalization group (DMRG) techniques. The parameter that controls the
hopping decay acts as the effective, non-integer spatial dimensionality
. For real-valued hopping amplitudes we identify analytically a range
of parameters for which power-law hopping suppress fluctuations and restore
superconducting long-range order for any . A detailed DMRG
analysis fully supports these findings. These results are also of direct
relevance to quantum magnetism as our model can be mapped onto a S=1/2 XXZ
spin-chain with power-law decaying couplings, which can be studied
experimentally by cold ion-trap techniques.Comment: 8 pages, 2 figures. New version with new figures, new references,
clarified discussion on the variational method and an Appendix for detail
Inhomogenous pairing and enhancement of superconductivity in large Sn nanograins
A substantial enhancement of the superconducting gap was recently reported in
clean, large ~30nm, and close to hemispherical Sn grains. A satisfactory
explanation of this behaviour is still missing as shell effects caused by
fluctuations of the spectral density or surface phonons are negligible in this
region. Here we show that this enhancement is caused by spatial inhomogeneities
of the Cooper's pairs density of probability. In the mean field approach that
we employ these inhomogeneities are closely related to the eigenstates of the
one-body problem, namely, a particle in a hemispherical shaped potential. The
parameter free theoretical prediction agrees well with the experimental
results. A similar enhancement is predicted for other weakly coupled
superconductors.Comment: 5 pages, 1 figure, proceedings conference "Quantum in Complex
Matter:Superconductivity, Magnetism and Ferroelectricity" Ischia, May 27th -
June 1st 201
Universality and Thouless energy in the supersymmetric Sachdev-Ye-Kitaev Model
We investigate the supersymmetric Sachdev-Ye-Kitaev (SYK) model, Majorana
fermions with infinite range interactions in dimensions. We have found
that, close to the ground state , discrete symmetries alter
qualitatively the spectral properties with respect to the non-supersymmetric
SYK model. The average spectral density at finite , which we compute
analytically and numerically, grows exponentially with for .
However the chiral condensate, which is normalized with respect the total
number of eigenvalues, vanishes in the thermodynamic limit. Slightly above , the spectral density grows exponential with the energy. Deep in the
quantum regime, corresponding to the first eigenvalues, the average
spectral density is universal and well described by random matrix ensembles
with chiral and superconducting discrete symmetries. The dynamics for is investigated by level fluctuations. Also in this case we find
excellent agreement with the prediction of chiral and superconducting random
matrix ensembles for eigenvalues separations smaller than the Thouless energy,
which seems to scale linearly with . Deviations beyond the Thouless energy,
which describes how ergodicity is approached, are universality characterized by
a quadratic growth of the number variance. In the time domain, we have found
analytically that the spectral form factor , obtained from the connected
two-level correlation function of the unfolded spectrum, decays as for
times shorter but comparable to the Thouless time with related to the
coefficient of the quadratic growth of the number variance. Our results provide
further support that quantum black holes are ergodic and therefore can be
classified by random matrix theory.Comment: 24 pages, 6 figures, added reference
Shape resonances and shell effects in thin-film multiband superconductors
We study analytically the evolution of superconductivity in clean
quasi-two-dimensional multiband supercon- ductors as the film thickness enters
the nanoscale region by mean-field and semiclassical techniques. Tunneling into
the substrate and finite lateral size effects, which are important in
experiments, are also considered in our model. As a result, it is possible to
investigate the interplay between quantum coherence effects, such as shape
resonances and shell effects, with the potential to enhance superconductivity,
and the multiband structure and the coupling to the substrate that tend to
suppress it. The case of magnesium diboride, which is the conventional
superconductor with the highest critical temperature, is discussed in detail.
Once the effect of the substrate is considered, we still observe quantum size
effects such as the oscillation of the critical temperature with the thickness
but without a significant enhancement of superconductivity. In thin films with
a sufficiently longer superconducting coherence length, it is, however,
possible to increase the critical temperature above the bulk limit by tuning
the film thickness or lateral size.Comment: 11 pages, 8 figure
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