17 research outputs found
Star formation in evolving molecular clouds
Molecular clouds are the principle stellar nurseries of our universe, keeping
them in the focus of both observational and theoretical studies. From
observations, some of the key properties of molecular clouds are well known but
many questions regarding their evolution and star formation activity remain
open. While numerical simulations feature a large number and complexity of
involved physical processes, this plenty of effects may hide the fundamentals
that determine the evolution of molecular clouds and enable the formation of
stars. Purely analytical models, on the other hand, tend to suffer from rough
approximations or a lack of completeness, limiting their predictive power. In
this paper, we present a model that incorporates central concepts of
astrophysics as well as reliable results from recent simulations of molecular
clouds and their evolutionary paths. Based on that, we construct a
self-consistent semi-analytical framework that describes the formation,
evolution and star formation activity of molecular clouds, including a number
of feedback effects to account for the complex processes inside those objects.
The final equation system is solved numerically but at much lower computational
expense than, e.g., hydrodynamical descriptions of comparable systems. The
model presented in this paper agrees well with a broad range of observational
results, showing that molecular cloud evolution can be understood as an
interplay between accretion, global collapse, star formation and stellar
feedback.Comment: 11 pages, 11 figures. Accepted for publication in A&
Second generation planet formation in NN Serpentis?
In this paper, we study the general impact of stellar mass-ejection events in
planetary orbits in post-common envelope binaries with circumbinary planets
like those around NN Serpentis. We discuss a set of simple equations that
determine upper and lower limits for orbital expansion and investigate the
effect of initial eccentricity. We deduce the range of possible semi-major axes
and initial eccentricity values of the planets prior to the common-envelope
event. In addition to spherically-symmetric mass-ejection events, we consider
planetary dynamics under the influence of an expanding disk. In order to have
survived, we suggest that the present planets in NN Ser must have had
semi-major axes AU and high eccentricity values which is
in conflict with current observations. Consequently, we argue that these
planets were not formed together with their hosting stellar system, but rather
originated from the fraction of matter of the envelope that remained bound to
the binary. According to the cooling age of the white dwarf primary of
yr, the planets around NN Ser might be the youngest known so far and open up a
wide range of further study of second generation planet formation.Comment: 4 pages, 2 figure
The physics of the Applegate mechanism: Eclipsing time variations from magnetic activity
Since its proposal in 1992, the Applegate mechanism has been discussed as a
potential intrinsical mechanism to explain transit timing variations in various
kinds of close binary systems. Most analytical arguments presented so far
focused on the energetic feasibility of the mechanism, while applying rather
crude one- or two-zone prescriptions to describe the exchange of angular
momentum within the star. In this paper, we present the most detailed approach
to date to describe the physics giving rise to the modulation period from
kinetic and magnetic fluctuations. Assuming moderate levels of stellar
parameter fluctuations, we find that the resulting binary period variations are
one or two orders of magnitude lower than the observed values in RS-CVn like
systems, supporting the conclusion of existing theoretical work that the
Applegate mechanism may not suffice to produce the observed variations in these
systems. The most promising Applegate candidates are low-mass
post-common-envelope binaries (PCEBs) with binary separations and secondary masses in the range of
and .Comment: 10 pages, 8 figures. Accepted for publication in A&
The Applegate mechanism in Post-Common-Envelope Binaries: Investigating the role of rotation
Eclipsing time variations (ETVs) are observed in many close binary systems.
In particular, for several post-common-envelope binaries (PCEBs) that consist
of a white dwarf and a main sequence star, the O-C diagram suggests that real
or apparent orbital period variations are driven by Jupiter-mass planets or as
a result of magnetic activity, the so-called Applegate mechanism. The latter
explains orbital period variations as a result of changes in the stellar
quadrupole moment due to magnetic activity. We explore the feasibility of
driving ETVs via the Applegate mechanism for a sample of PCEB systems,
including a range of different rotations. Using the MESA code we evolve 12
stars with different masses and rotation rates. We apply a simple dynamo model
to their radial profiles to investigate on which scale the predicted activity
cycle matches the observed modulation period, and quantify the uncertainty, and
further calculate the required energies to drive que Applegate mechanism. We
show that the Applegate mechanism is energetically feasible in 5 PCEB systems,
and note that these are the systems with the highest rotation rate compared to
the critical rotation rate of the main-sequence star. The results suggest that
the ratio of physical to critical rotation in the main sequence star is an
important indicator for the feasibility of Applegate's mechanism, but exploring
larger samples will be necessary to probe this hypothesis.Comment: 9 pages, 5 figures. Accepted for publication in A&
A new approach to distant solar system object detection in large survey data sets
The recently postulated existence of a giant ninth planet in our solar system
has sparked search efforts for distant solar system objects (SSOs) both via new
observations and archival data analysis. Due to the likely faintness of the
object in the optical and infrared regime, it has so far eluded detection. We
set out to re-analyze data acquired by the Wide-Field Infrared Survey Explorer
(WISE), an all-sky survey well suited for the detection of SSOs. We present a
new approach to SSO detection via parallactic fitting. Using the heliocentric
distance as a fit parameter, our code transforms groups of three or more single
observation point sources to heliocentric coordinates under the assumption that
all data stem from an object. The fact that the orbit of a distant SSO is
approximately linear in heliocentric coordinates over long time-scales can be
utilized to produce candidates, which can then be confirmed with follow-up
observations. We demonstrate the feasibility of the approach by a posteriori
detecting the outer SSO Makemake within WISE data. An all-sky search for Planet
Nine yielded no detection. While the postulated Planet Nine eluded detection by
our algorithm, we tentatively predict that this new approach to moving-object
analysis will enable the discovery of new distant SSOs that cannot be
discovered by other algorithms. Especially in cases of sparse data observed
over long time spans, our approach is unique and robust due to the use of only
one fit parameter.Comment: 9 pages, 10 figure
Long-term variations in the X-ray activity of HR 1099
Although timing variations in close binary systems have been studied for a
long time, their underlying causes are still unclear. A possible explanation is
the so-called Applegate mechanism, where a strong, variable magnetic field can
periodically change the gravitational quadrupole moment of a stellar component,
thus causing observable period changes. One of the systems exhibiting such
strong orbital variations is the RS CVn binary HR 1099, whose activity cycle
has been studied by various authors via photospheric and chromospheric activity
indicators, resulting in contradicting periods. We aim at independently
determining the magnetic activity cycle of HR 1099 using archival X-ray data to
allow for a comparison to orbital period variations. Archival X-ray data from
80 different observations of HR 1099 acquired with 12 different X-ray
facilities and covering almost four decades were used to determine X-ray fluxes
in the energy range of 2-10 keV via spectral fitting and flux conversion. Via
the Lomb-Scargle periodogram we analyze the resulting long-term X-ray light
curve to search for periodicities. We do not detect any statistically
significant periodicities within the X-ray data. An analysis of optical data of
HR 1099 shows that the derivation of such periods is strongly dependent on the
time coverage of available data, since the observed optical variations strongly
deviate from a pure sine wave. We argue that this offers an explanation as to
why other authors derive such a wide range of activity cycle periods based on
optical data. We conclude that our analysis constitutes the longest stellar
X-ray activity light curve acquired to date, yet the still rather sparse
sampling of the X-ray data, along with stochastic flaring activity, does not
allow for the independent determination of an X-ray activity cycle.Comment: 8 pages, 6 figures, 2 tables accepted for publication in A&
Long-term eclipse timing of white dwarf binaries: an observational hint of a magnetic mechanism at work
We present a long-term programme for timing the eclipses of white dwarfs in close binaries to measure apparent and/or real variations in their orbital periods. Our programme includes 67 close binaries, both detached and semi-detached and with M-dwarfs, K-dwarfs, brown dwarfs or white dwarfs secondaries. In total, we have observed more than 650 white dwarf eclipses. We use this sample to search for orbital period variations and aim to identify the underlying cause of these variations. We find that the probability of observing orbital period variations increases significantly with the observational baseline. In particular, all binaries with baselines exceeding 10 yr, with secondaries of spectral type K2 – M5.5, show variations in the eclipse arrival times that in most cases amount to several minutes. In addition, among those with baselines shorter than 10 yr, binaries with late spectral type (>M6), brown dwarf or white dwarf secondaries appear to show no orbital period variations. This is in agreement with the so-called Applegate mechanism, which proposes that magnetic cycles in the secondary stars can drive variability in the binary orbits. We also present new eclipse times of NN Ser, which are still compatible with the previously published circumbinary planetary system model, although only with the addition of a quadratic term to the ephemeris. Finally, we conclude that we are limited by the relatively short observational baseline for many of the binaries in the eclipse timing programme, and therefore cannot yet draw robust conclusions about the cause of orbital period variations in evolved, white dwarf binaries
The sdB pulsating star V391 Peg and its putative giant planet revisited after 13 years of time-series photometric data
V391 Peg (alias HS 2201+2610) is a subdwarf B (sdB) pulsating star that shows both p- and g-modes. By studying the arrival times
of the p-mode maxima and minima through the O–C method, in a previous article the presence of a planet was inferred with an
orbital period of 3.2 years and a minimum mass of 3.2 MJup. Here we present an updated O–C analysis using a larger data set of
1066 h of photometric time series (∼2.5× larger in terms of the number of data points), which covers the period between 1999 and 2012
(compared with 1999–2006 of the previous analysis). Up to the end of 2008, the new O–C diagram of the main pulsation frequency (f1)
is compatible with (and improves) the previous two-component solution representing the long-term variation of the pulsation period
(parabolic component) and the giant planet (sine wave component). Since 2009, the O–C trend of f1 changes, and the time derivative
of the pulsation period (p˙) passes from positive to negative; the reason of this change of regime is not clear and could be related to
nonlinear interactions between different pulsation modes. With the new data, the O–C diagram of the secondary pulsation frequency
(f2) continues to show two components (parabola and sine wave), like in the previous analysis. Various solutions are proposed to fit
the O–C diagrams of f1 and f2, but in all of them, the sinusoidal components of f1 and f2 differ or at least agree less well than before.
The nice agreement found previously was a coincidence due to various small effects that are carefully analyzed. Now, with a larger
dataset, the presence of a planet is more uncertain and would require confirmation with an independent method. The new data allow
us to improve the measurement of p˙ for f1 and f2: using only the data up to the end of 2008, we obtain p˙ 1 = (1.34 ± 0.04) × 10−12 and
p˙ 2 = (1.62 ± 0.22) × 10−12. The long-term variation of the two main pulsation periods (and the change of sign of p˙ 1) is visible also in
direct measurements made over several years. The absence of peaks near f1 in the Fourier transform and the secondary peak close to
f2 confirm a previous identification as l = 0 and l = 1, respectively, and suggest a stellar rotation period of about 40 days. The new data
allow constraining the main g-mode pulsation periods of the star
Spectropolarimetry of stars across the H-R diagram
The growing sample of magnetic stars shows a remarkable diversity in the
properties of their magnetic fields. The overall goal of current studies is to
understand the origin, evolution, and structure of stellar magnetic fields in
stars of different mass at different evolutionary stages. In this chapter we
discuss recent measurements together with the underlying assumptions in the
interpretation of data and the requirements, both observational and
theoretical, for obtaining a realistic overview of the role of magnetic fields
in various types of stars.Comment: 23 pages, 3 figures, chapter 7 of "Astronomical Polarisation from the
Infrared to Gamma Rays", published in Astrophysics and Space Science Library
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