580 research outputs found
Exoplanet Research with the Stratospheric Observatory for Infrared Astronomy (SOFIA)
When the Stratospheric Observatory for Infrared Astronomy (SOFIA) was
conceived and its first science cases defined, exoplanets had not been
detected. Later studies, however, showed that optical and near-infrared
photometric and spectrophotometric follow-up observations during planetary
transits and eclipses are feasible with SOFIA's instrumentation, in particular
with the HIPO-FLITECAM and FPI+ optical and near infrared (NIR) instruments.
Additionally, the airborne-based platform SOFIA has a number of unique
advantages when compared to other ground- and space-based observatories in this
field of research. Here we will outline these theoretical advantages, present
some sample science cases and the results of two observations from SOFIA's
first five observation cycles -- an observation of the Hot Jupiter HD 189733b
with HIPO and an observation of the Super-Earth GJ 1214b with FLIPO and FPI+.
Based on these early products available to this science case, we evaluate
SOFIA's potential and future perspectives in the field of optical and infrared
exoplanet spectrophotometry in the stratosphere.Comment: Invited review chapter, accepted for publication in "Handbook of
Exoplanets" edited by H.J. Deeg and J.A. Belmonte, Springer Reference Work
On the Use of Multipole Expansion in Time Evolution of Non-linear Dynamical Systems and Some Surprises Related to Superradiance
A new numerical method is introduced to study the problem of time evolution
of generic non-linear dynamical systems in four-dimensional spacetimes. It is
assumed that the time level surfaces are foliated by a one-parameter family of
codimension two compact surfaces with no boundary and which are conformal to a
Riemannian manifold C. The method is based on the use of a multipole expansion
determined uniquely by the induced metric structure on C. The approach is fully
spectral in the angular directions. The dynamics in the complementary 1+1
Lorentzian spacetime is followed by making use of a fourth order finite
differencing scheme with adaptive mesh refinement.
In checking the reliability of the introduced new method the evolution of a
massless scalar field on a fixed Kerr spacetime is investigated. In particular,
the angular distribution of the evolving field in to be superradiant scattering
is studied. The primary aim was to check the validity of some of the recent
arguments claiming that the Penrose process, or its field theoretical
correspondence---superradiance---does play crucial role in jet formation in
black hole spacetimes while matter accretes onto the central object. Our
findings appear to be on contrary to these claims as the angular dependence of
a to be superradiant scattering of a massless scalar field does not show any
preference of the axis of rotation. In addition, the process of superradiance,
in case of a massless scalar field, was also investigated. On contrary to the
general expectations no energy extraction from black hole was found even though
the incident wave packets was fine tuned to be maximally superradiant. Instead
of energy extraction the to be superradiant part of the incident wave packet
fails to reach the ergoregion rather it suffers a total reflection which
appears to be a new phenomenon.Comment: 49 pages, 11 figure
The power of wavelets in analysis of transit and phase curves in presence of stellar variability and instrumental noise I. Method and validation
Stellar photometric variability and instrumental effects, like cosmic ray
hits, data discontinuities, data leaks, instrument aging etc. cause
difficulties in the characterization of exoplanets and have an impact on the
accuracy and precision of the modelling and detectability of transits,
occultations and phase curves. This paper aims to make an attempt to improve
the transit, occultation and phase-curve modelling in the presence of strong
stellar variability and instrumental noise. We invoke the wavelet-formulation
to reach this goal. We explore the capabilities of the software package Transit
and Light Curve Modeller (TLCM). It is able to perform a joint radial velocity
and light curve fit or light curve fit only. It models the transit,
occultation, beaming, ellipsoidal and reflection effects in the light curves
(including the gravity darkening effect, too). The red-noise, the stellar
variability and instrumental effects are modelled via wavelets. The wavelet-fit
is constrained by prescribing that the final white noise level must be equal to
the average of the uncertainties of the photometric data points. This helps to
avoid the overfit and regularizes the noise model. The approach was tested by
injecting synthetic light curves into Kepler's short cadence data and then
modelling them. The method performs well over a certain signal-to-noise (S/N)
ratio. In general a S/N ratio of 10 is needed to get good results but some
parameters requires larger S/N, some others can be retrieved at lower S/Ns. We
give limits in terms of signal-to-noise ratio for every studied system
parameter which is needed to accurate parameter retrieval. The wavelet-approach
is able to manage and to remove the impacts of data discontinuities, cosmic ray
events, long-term stellar variability and instrument ageing, short term stellar
variability and pulsation and flares among others. (...)Comment: Submitted to A&A. 11 pages, 14 figure
Density Functional Molecular Computations on Protonated Serotonin in the Gas Phase and Various Solvent Media
5-Hydroxytryptamine (serotonin) was geometry optimized at the
B3YP/6-31G(d) level of theory to determine the energetically most
favourable conformations of the aromatic hydroxyl group and the
protonated ethylamine side chain. The hydroxyl group was found to be
most stable at anti for all conformations, and the two lowest energy
gas phase conformers found were: chi(2) = g(+), chi(3) = g(-) and
chi(2) = g(-), chi(3) = g(+). The protonated amino group was found
equally stable at g+, g- and anti. The transition structures linking
each gas phase minimum were also computed. Minima found were subjected
to solvation calculations in chloroform, DMSO, ethanol and water, which
shifted their relative stabilities. (C) 2002 Elsevier Science B.V. All
rights reserved
Density Functional Molecular Study on the Full Conformational Space of the S-4-(2-Hydroxypropoxy)carbazol Fragment of Carvedilol (1-(9H−Carbazol-4-yloxy)-3- [2-(2-methoxyphenoxy)ethylamino]-2-propanol) in Vacuum and in Different Solvent Media
Density functional theory (DFT) conformational analysis was carried out
on the potential energy hypersurface (PEHS) of the carbazole-containing
molecular fragment, S-4-(2-hydroxypropoxy)-carbazol, of the chiral
cardiovascular drug molecule carvedilol,
(1-(9H-carbazol-4-yloxy)-3-[2-(2-methoxy-phenoxy)ethylamino]-2-propanol)
. The PEHS was computed in vacuum, chloroform, ethanol, DMSO, and water
at the B3LYP/6-31G(d) level of theory. The carbazole ring system was
confirmed to be planar, and the resultant PEHS in vacuum contained 19
converged minima, of which the global minima possessed a conformation
with chi(1), chi(2), and chi(3) in the anti position and chi(10) in the
g position. Conformer stability for the S-4-(2-hydroxypropoxy)carbazol
PEHS was influenced by intramolecular hydrogen bonding. Tomasi PCM
reaction-field calculations revealed that the lowest SCF energies,
relative conformer energies, and solvation free energies (DeltaG
(solvation)) for the S-4-(2-hydroxypropoxy)carbazol PEHS were in protic
solvents, ethanol and water, because of the larger hydrogen bond donor
values of these solvents, which aid in stabilization of the dipole
moment created by the carbazole ring system and the oxygen and nitrogen
atoms. However, solvent effects contributed most significantly to the
stabilization of S-4-(2-hydroxypropoxy)carbazol conformers that
contained no internal hydrogen bonding, whereas solvent effects were
not as important for conformers that contained intramolecular hydrogen
bonding
Open Charm Enhancement in Pb+Pb Collisions at SPS
The statistical coalescence model for the production of open and hidden charm
is considered within the canonical ensemble formulation. The data for the
J/\psi multiplicity in Pb+Pb collisions at 158 A GeV are used for the model
prediction of the open charm yield. We find a strong enhancement of the open
charm production, by a factor of about 2--4, over the standard hard-collision
model extrapolation from nucleon-nucleon to nucleus-nucleus collisions. A
possible mechanism of the open charm enhancement in A+A collisions at the SPS
energies is proposed.Comment: 4 pages, Late
Gravitational waves from spinning eccentric binaries
This paper is to introduce a new software called CBwaves which provides a
fast and accurate computational tool to determine the gravitational waveforms
yielded by generic spinning binaries of neutron stars and/or black holes on
eccentric orbits. This is done within the post-Newtonian (PN) framework by
integrating the equations of motion and the spin precession equations while the
radiation field is determined by a simultaneous evaluation of the analytic
waveforms. In applying CBwaves various physically interesting scenarios have
been investigated. In particular, we have studied the appropriateness of the
adiabatic approximation, and justified that the energy balance relation is
indeed insensitive to the specific form of the applied radiation reaction term.
By studying eccentric binary systems it is demonstrated that circular template
banks are very ineffective in identifying binaries even if they possess tiny
residual orbital eccentricity. In addition, by investigating the validity of
the energy balance relation we show that, on contrary to the general
expectations, the post-Newtonian approximation should not be applied once the
post-Newtonian parameter gets beyond the critical value .
Finally, by studying the early phase of the gravitational waves emitted by
strongly eccentric binary systems---which could be formed e.g. in various
many-body interactions in the galactic halo---we have found that they possess
very specific characteristics which may be used to identify these type of
binary systems.Comment: 37 pages, 18 figures, submitted to Class. Quantum Gra
Strange hyperon and antihyperon production from quark and string-rope matter
Hyperon and antihyperon production is investigated using two microscopical
models: {\bf (1)} the fast hadronization of quark matter as given by the ALCOR
model; {\bf (2)} string formation and fragmentation as in the HIJING/B model.
We calculate the particle numbers and momentum distributions for Pb+Pb
collisions at CERN SPS energies in order to compare the two models with each
other and with the available experimental data. We show that these two
theoretical approaches give similar yields for the hyperons, but strongly
differ for antihyperons.Comment: 11 pages, Latex, 3 EPS figures, contribution to the Proceedings of
the 4th International Conference on Strangeness in Quark Matter (SQM'98),
Padova, Italy, 20-24 July 199
Revisiting the transits of CoRoT-7b at a lower activity level
CoRoT-7b, the first super-Earth with measured radius discovered, has opened
the new field of rocky exoplanets characterisation. To better understand this
interesting system, new observations were taken with the CoRoT satellite.
During this run 90 new transits were obtained in the imagette mode. These were
analysed together with the previous 151 transits obtained in the discovery run
and HARPS radial velocity observations to derive accurate system parameters. A
difference is found in the posterior probability distribution of the transit
parameters between the previous CoRoT run (LRa01) and the new run (LRa06). We
propose this is due to an extra noise component in the previous CoRoT run
suspected to be transit spot occultation events. These lead to the mean transit
shape becoming V-shaped. We show that the extra noise component is dominant at
low stellar flux levels and reject these transits in the final analysis. We
obtained a planetary radius, , in agreement
with previous estimates. Combining the planetary radius with the new mass
estimates results in a planetary density of
which is consistent with a rocky composition. The CoRoT-7 system remains an
excellent test bed for the effects of activity in the derivation of planetary
parameters in the shallow transit regime.Comment: 13 pages, 13 figures, accepted to A&
Analysis of multiple compound–protein interactions reveals novel bioactive molecules
The authors use machine learning of compound-protein interactions to explore drug polypharmacology and to efficiently identify bioactive ligands, including novel scaffold-hopping compounds for two pharmaceutically important protein families: G-protein coupled receptors and protein kinases
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