42,832 research outputs found
Plain fundamentals of Fundamental Planes: Analytics and algorithms
The coefficients a and b of the Fundamental Plane relation R ~ Sigma^a I^b
depend on whether one minimizes the scatter in the R direction or orthogonal to
the Plane. We provide explicit expressions for a and b (and confidence limits)
in terms of the covariances between logR, logSigma and logI. Our analysis is
more generally applicable to any other correlations between three variables:
e.g., the color-magnitude-Sigma relation, the L-Sigma-Mbh relation, or the
relation between the X-ray luminosity, Sunyaev-Zeldovich decrement and optical
richness of a cluster, so we provide IDL code which implements these ideas, and
we show how our analysis generalizes further to correlations between more than
three variables. We show how to account for correlated errors and selection
effects, and quantify the difference between the direct, inverse and orthogonal
fit coefficients. We show that the three vectors associated with the
Fundamental Plane can all be written as simple combinations of a and b because
the distribution of I is much broader than that of Sigma, and Sigma and I are
only weakly correlated. Why this should be so for galaxies is a fundamental
open question about the physics of early-type galaxy formation. If luminosity
evolution is differential, and Rs and Sigmas do not evolve, then this is just
an accident: Sigma and I must have been correlated in the past. On the other
hand, if the (lack of) correlation is similar to that at the present time, then
differential luminosity evolution must have been accompanied by structural
evolution. A model in which the luminosities of low-L galaxies evolve more
rapidly than do those of higher-L galaxies is able to produce the observed
decrease in a (by a factor of 2 at z~1) while having b decrease by only about
20 percent. In such a model, the Mdyn/L ratio is a steeper function of Mdyn at
higher z.Comment: 11 pages, 1 figure, associated IDL code, MNRAS accepte
Counting coloured planar maps: differential equations
We address the enumeration of q-coloured planar maps counted bythe number of
edges and the number of monochromatic edges. We prove that the associated
generating function is differentially algebraic,that is, satisfies a
non-trivial polynomial differential equation withrespect to the edge variable.
We give explicitly a differential systemthat characterizes this series. We then
prove a similar result for planar triangulations, thus generalizing a result of
Tutte dealing with their proper q-colourings. Instatistical physics terms, we
solvethe q-state Potts model on random planar lattices. This work follows a
first paper by the same authors, where the generating functionwas proved to be
algebraic for certain values of q,including q=1, 2 and 3. It isknown to be
transcendental in general. In contrast, our differential system holds for an
indeterminate q.For certain special cases of combinatorial interest (four
colours; properq-colourings; maps equipped with a spanning forest), we derive
from this system, in the case of triangulations, an explicit differential
equation of order 2 defining the generating function. For general planar maps,
we also obtain a differential equation of order 3 for the four-colour case and
for the self-dual Potts model.Comment: 43 p
Bijective counting of Kreweras walks and loopless triangulations
We consider lattice walks in the plane starting at the origin, remaining in
the first quadrant and made of West, South and North-East steps. In 1965,
Germain Kreweras discovered a remarkably simple formula giving the number of
these walks (with prescribed length and endpoint). Kreweras' proof was very
involved and several alternative derivations have been proposed since then. But
the elegant simplicity of the counting formula remained unexplained. We give
the first purely combinatorial explanation of this formula. Our approach is
based on a bijection between Kreweras walks and triangulations with a
distinguished spanning tree. We obtain simultaneously a bijective way of
counting loopless triangulations.Comment: 25 page
A simple model of trees for unicellular maps
We consider unicellular maps, or polygon gluings, of fixed genus. A few years
ago the first author gave a recursive bijection transforming unicellular maps
into trees, explaining the presence of Catalan numbers in counting formulas for
these objects. In this paper, we give another bijection that explicitly
describes the "recursive part" of the first bijection. As a result we obtain a
very simple description of unicellular maps as pairs made by a plane tree and a
permutation-like structure. All the previously known formulas follow as an
immediate corollary or easy exercise, thus giving a bijective proof for each of
them, in a unified way. For some of these formulas, this is the first bijective
proof, e.g. the Harer-Zagier recurrence formula, the Lehman-Walsh formula and
the Goupil-Schaeffer formula. We also discuss several applications of our
construction: we obtain a new proof of an identity related to covered maps due
to Bernardi and the first author, and thanks to previous work of the second
author, we give a new expression for Stanley character polynomials, which
evaluate irreducible characters of the symmetric group. Finally, we show that
our techniques apply partially to unicellular 3-constellations and to related
objects that we call quasi-constellations.Comment: v5: minor revision after reviewers comments, 33 pages, added a
refinement by degree of the Harer-Zagier formula and more details in some
proof
Curvature in the color-magnitude relation but not in color-sigma: Major dry mergers at M* > 2 x 10^11 Msun?
The color-magnitude relation of early-type galaxies differs slightly but
significantly from a pure power-law, curving downwards at low and upwards at
large luminosities (Mr>-20.5 and Mr<-22.5). This remains true of the color-size
relation, and is even more apparent with stellar mass (M* < 3x10^10 Msun and M*
> 2x10^11 Msun). The upwards curvature at the massive end does not appear to be
due to stellar population effects. In contrast, the color-sigma relation is
well-described by a single power law. Since major dry mergers change neither
the colors nor sigma, but they do change masses and sizes, the clear features
observed in the scaling relations with M*, but not with sigma > 150 km/s,
suggest that M* > 2x10^11 Msun is the scale above which major dry mergers
dominate the assembly history. We discuss three models of the merger histories
since z ~ 1 which are compatible with our measurements. In all three models,
dry mergers are responsible for the flattening of the color-M* relation at M* >
3x10^10 Msun - wet mergers only matter at smaller masses. At M* > 2 x 10^11
Msun, the merger histories in one model are dominated by major rather than
minor dry mergers, as suggested by the axis ratio and color gradient trends. In
another, although both major and minor mergers occur at the high mass end, the
minor mergers contribute primarily to the formation of the ICL, rather than to
the mass growth of the central massive galaxy. A final model assumes that the
reddest objects were assembled by a mix of major and minor dry mergers.Comment: 22 pages, 22 figures and 3 tables. Accepted for publication in MNRA
Physical Origin of the One-Quarter Exact Exchange in Density Functional Theory
Exchange interactions are a manifestation of the quantum mechanical nature of
the electrons and play a key role in predicting the properties of materials
from first principles. In density functional theory (DFT), a widely used
approximation to the exchange energy combines fractions of density-based and
Hartree-Fock (exact) exchange. This so-called hybrid DFT scheme is accurate in
many materials, for reasons that are not fully understood. Here we show that a
1/4 fraction of exact exchange plus a 3/4 fraction of density-based exchange is
compatible with a correct quantum mechanical treatment of the exchange energy
of an electron pair in the unpolarized electron gas. We also show that the 1/4
exact-exchange fraction mimics a correlation interaction between doubly-excited
electronic configurations. The relation between our results and trends observed
in hybrid DFT calculations is discussed, along with other implications
Ideals of varieties parameterized by certain symmetric tensors
The ideal of a Segre variety is generated by the 2-minors of a generic hypermatrix of indeterminates. We extend this result to the case of SegreVeronese varieties. The main tool is the concept of “weak generic hypermatrix” which allows us to treat also the case of projection of Veronese surfaces from a set of generic points and of Veronese varieties from a Cohen-Macaulay subvariety of codimension 2
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