790 research outputs found
How does the grouping scheme affect the Wiener Filter reconstruction of the local Universe?
High quality reconstructions of the three dimensional velocity and density
fields of the local Universe are essential to study the local Large Scale
Structure. In this paper, the Wiener Filter reconstruction technique is applied
to galaxy radial peculiar velocity catalogs to understand how the Hubble
constant (H0) value and the grouping scheme affect the reconstructions. While
H0 is used to derive radial peculiar velocities from galaxy distance
measurements and total velocities, the grouping scheme serves the purpose of
removing non linear motions. Two different grouping schemes (based on the
literature and a systematic algorithm) as well as five H0 values ranging from
72 to 76 km/s/Mpc are selected. The Wiener Filter is applied to the resulting
catalogs. Whatever grouping scheme is used, the larger H0 is, the larger the
infall onto the local Volume is. However, this conclusion has to be strongly
mitigated: a bias minimization scheme applied to the catalogs after grouping
suppresses this effect. At fixed H0, reconstructions obtained with catalogs
grouped with the different schemes exhibit structures at the proper location in
both cases but the latter are more contrasted in the less aggressive scheme
case: having more constraints permits an infall from both sides onto the
structures to reinforce their overdensity. Such findings highlight the
importance of a balance between grouping to suppress non linear motions and
preserving constraints to produce an infall onto structures expected to be
large overdensities. Such an observation is promising to perform constrained
simulations of the local Universe including its massive clusters.Comment: Accepted for publication in MNRAS, 10 pages, 6 figures, 3 table
Long-range excitations in time-dependent density functional theory
Adiabatic time-dependent density functional theory fails for excitations of a
heteroatomic molecule composed of two open-shell fragments at large separation.
Strong frequency-dependence of the exchange-correlation kernel is necessary for
both local and charge-transfer excitations. The root of this is static
correlation created by the step in the exact Kohn-Sham ground-state potential
between the two fragments. An approximate non-empirical kernel is derived for
excited molecular dissociation curves at large separation. Our result is also
relevant for the usual local and semi-local approximations for the ground-state
potential, as static correlation there arises from the coalescence of the
highest occupied and lowest unoccupied orbital energies as the molecule
dissociates.Comment: 7 pages, 2 figure
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Theory of Excitation Broadening Using Time-Dependent Density Functional Theory for Open Quantum Systems
The Casida equations of linear response TDDFT are extended to calculate linear spectra of open quantum systems evolving according to a Markovian master equation. By mapping a many-body open quantum system onto an open, non-interacting Kohn-Sham system, extrinsic line broadening due to electron-bath coupling can be described exactly within TDDFT. The structure of the resulting matrix equations are analyzed for the generic case of electrons linearly coupled to a harmonic bath within Redfield theory. An approximate form of the exchange-correlation kernel based on first-order G\"orling-Levy perturbation theory is derived.Chemistry and Chemical Biolog
Computer analyses suggest interactions of non-muscle filamin with lipid membranes
AbstractIt is concluded from structure predictions of the primary amino acid sequence by computer analyses that two segments of non-muscle filamin could facilitate lipid membrane attachment or anchoring. Residues 49–71 of the amino-terminal may attach to phospholipid membranes, and residues 131–155 may anchor in the hydrophobic region of lipid membranes
Exciton coherence lifetimes from electronic structure
We model the coherent energy transfer of an electronic excitation within
covalently linked aromatic homodimers from first-principles, to answer whether
the usual models of the bath calculated via detailed electronic structure
calculations can reproduce the key dynamics. For these systems the timescales
of coherent transport are experimentally known from time-dependent polarization
anisotropy measurements, and so we can directly assess the whether current
techniques might be predictive for this phenomenon. Two choices of electronic
basis states are investigated, and their relative merits discussed regarding
the predictions of the perturbative model. The coupling of the electronic
degrees of freedom to the nuclear degrees of freedom is calculated rather than
assumed, and the fluorescence anisotropy decay is directly reproduced.
Surprisingly we find that although TDDFT absolute energies are routinely in
error by orders of magnitude more than the coupling energy, the coherent
transport properties of these dimers can be semi-quantitatively reproduced from
first-principles. The directions which must be pursued to yield predictive and
reliable prediction of coherent transport are suggested.Comment: 22 pages, 7 figure
A correlated-polaron electronic propagator: open electronic dynamics beyond the Born-Oppenheimer approximation
In this work we develop a theory of correlated many-electron dynamics dressed
by the presence of a finite-temperature harmonic bath. The theory is based on
the ab-initio Hamiltonian, and thus well-defined apart from any
phenomenological choice of collective basis states or electronic coupling
model. The equation-of-motion includes some bath effects non-perturbatively,
and can be used to simulate line- shapes beyond the Markovian approximation and
open electronic dynamics which are subjects of renewed recent interest. Energy
conversion and transport depend critically on the ratio of electron-electron
coupling to bath-electron coupling, which is a fitted parameter if a
phenomenological basis of many-electron states is used to develop an electronic
equation of motion. Since the present work doesn't appeal to any such basis, it
avoids this ambiguity. The new theory produces a level of detail beyond the
adiabatic Born-Oppenheimer states, but with cost scaling like the
Born-Oppenheimer approach. While developing this model we have also applied the
time-convolutionless perturbation theory to correlated molecular excitations
for the first time. Resonant response properties are given by the formalism
without phenomenological parameters. Example propagations with a developmental
code are given demonstrating the treatment of electron-correlation in
absorption spectra, vibronic structure, and decay in an open system.Comment: 25 pages 7 figure
Statistically bias-minimized peculiar velocity catalogs from Gibbs point processes and Bayesian inference
Galaxy peculiar velocities are excellent cosmological probes provided that
biases inherent to their measurements are contained before any study. This
paper proposes a new algorithm based on an object point process model whose
probability density is built to statistically reduce the effects of Malmquist
biases and uncertainties due to lognormal errors in radial peculiar velocity
catalogs. More precisely, a simulated annealing algorithm permits maximizing
the probability density describing the point process model. The resulting
configurations are bias-minimized catalogs. Tests are conducted on synthetic
catalogs mimicking the second and third distance modulus catalogs of the
Cosmicflows project from which peculiar velocity catalogs are derived. By
reducing the local peculiar velocity variance in catalogs by an order of
magnitude, the algorithm permits recovering the expected one while preserving
the small-scale velocity correlation. It also permits retrieving the expected
clustering. The algorithm is then applied to the observational catalogs. The
large-scale structure reconstructed with the Wiener-filter technique applied to
the bias-minimized observational catalogs matches with great success the local
cosmic web as depicted by redshift surveys of local galaxies. These new
bias-minimized versions of peculiar velocity catalogs can be used as a starting
point for several studies from possibly estimating the most probable Hubble
constant, H0, value to the production of simulations constrained to reproduce
the local Universe.Comment: Accepted for publication in A&A, 26 pages, 22 figures, 3 table
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