8,128 research outputs found
Models of Saturn's Interior Constructed with Accelerated Concentric Maclaurin Spheroid Method
The Cassini spacecraft's Grand Finale orbits provided a unique opportunity to
probe Saturn's gravity field and interior structure. Doppler measurements
yielded unexpectedly large values for the gravity harmonics J_6, J_8, and J_10
that cannot be matched with planetary interior models that assume uniform
rotation. Instead we present a suite of models that assume the planet's
interior rotates on cylinders, which allows us to match all the observed even
gravity harmonics. For every interior model, the gravity field is calculated
self-consistently with high precision using the Concentric Maclaurin Spheroid
(CMS) method. We present an acceleration technique for this method, which
drastically reduces the computational cost, allows us to efficiently optimize
model parameters, map out allowed parameter regions with Monte Carlo sampling,
and increases the precision of the calculated J_2n gravity harmonics to match
the error bars of the observations, which would be difficult without
acceleration. Based on our models, Saturn is predicted to have a dense central
core of 15-18 Earth masses and an additional 1.5-5 Earth masses of heavy
elements in the envelope. Finally, we vary the rotation period in the planet's
deep interior and determine the resulting oblateness, which we compare with the
value from radio occultation measurements by the Voyager spacecraft. We predict
a rotation period of 10:33:34 h +- 55s, which is in agreement with recent
estimates derived from ring seismology.Comment: 12 color figures, 5 tables, Astrophysical Journal, in press (2019
Efficient representation of fully many-body localized systems using tensor networks
We propose a tensor network encoding the set of all eigenstates of a fully
many-body localized system in one dimension. Our construction, conceptually
based on the ansatz introduced in Phys. Rev. B 94, 041116(R) (2016), is built
from two layers of unitary matrices which act on blocks of contiguous
sites.
We argue this yields an exponential reduction in computational time and
memory requirement as compared to all previous approaches for finding a
representation of the complete eigenspectrum of large many-body localized
systems with a given accuracy. Concretely, we optimize the unitaries by
minimizing the magnitude of the commutator of the approximate integrals of
motion and the Hamiltonian, which can be done in a local fashion. This further
reduces the computational complexity of the tensor networks arising in the
minimization process compared to previous work. We test the accuracy of our
method by comparing the approximate energy spectrum to exact diagonalization
results for the random field Heisenberg model on 16 sites. We find that the
technique is highly accurate deep in the localized regime and maintains a
surprising degree of accuracy in predicting certain local quantities even in
the vicinity of the predicted dynamical phase transition. To demonstrate the
power of our technique, we study a system of 72 sites and we are able to see
clear signatures of the phase transition. Our work opens a new avenue to study
properties of the many-body localization transition in large systems.Comment: Version 2, 16 pages, 16 figures. Larger systems and greater
efficienc
Tidal Response of Preliminary Jupiter Model
In anticipation of improved observational data for Jupiter's gravitational
field from the Juno spacecraft, we predict the static tidal response for a
variety of Jupiter interior models based on ab initio computer simulations of
hydrogen-helium mixtures. We calculate hydrostatic-equilibrium gravity terms
using the non-perturbative concentric Maclaurin Spheroid (CMS) method that
eliminates lengthy expansions used in the theory of figures. Our method
captures terms arising from the coupled tidal and rotational perturbations,
which we find to be important for a rapidly-rotating planet like Jupiter. Our
predicted static tidal Love number is 10\% larger than
previous estimates. The value is, as expected, highly correlated with the zonal
harmonic coefficient , and is thus nearly constant when plausible changes
are made to interior structure while holding fixed at the observed value.
We note that the predicted static might change due to Jupiter's dynamical
response to the Galilean moons, and find reasons to argue that the change may
be detectable, although we do not present here a theory of dynamical tides for
highly oblate Jovian planets. An accurate model of Jupiter's tidal response
will be essential for interpreting Juno observations and identifying tidal
signals from effects of other interior dynamics in Jupiter's gravitational
field.Comment: 10 Pages, 6 figures, 4 table
Fermionic Projected Entangled Pair States and Local U(1) Gauge Theories
Tensor networks, and in particular Projected Entangled Pair States (PEPS),
are a powerful tool for the study of quantum many body physics, thanks to both
their built-in ability of classifying and studying symmetries, and the
efficient numerical calculations they allow. In this work, we introduce a way
to extend the set of symmetric PEPS in order to include local gauge invariance
and investigate lattice gauge theories with fermionic matter. To this purpose,
we provide as a case study and first example, the construction of a fermionic
PEPS, based on Gaussian schemes, invariant under both global and local U(1)
gauge transformations. The obtained states correspond to a truncated U(1)
lattice gauge theory in 2 + 1 dimensions, involving both the gauge field and
fermionic matter. For the global symmetry (pure fermionic) case, these PEPS can
be studied in terms of spinless fermions subject to a p-wave superconducting
pairing. For the local symmetry (fermions and gauge fields) case, we find
confined and deconfined phases in the pure gauge limit, and we discuss the
screening properties of the phases arising in the presence of dynamical matter
Protecting the Wolf in Sheep\u27s Clothing: Perverse Consequences of the McKennon Rule
What follows is, first, a description of the typical scenarios that arise in after-acquired-evidence cases and the law surrounding McKennon. Section II discusses how the economic literature on information and signaling applies to such cases; section III elaborates upon the motives behind and the perversities of McKennon; and section IV offers conclusions
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