1,202 research outputs found
Apodization in high-contrast long-slit spectroscopy. Closer, deeper, fainter, cooler
The spectroscopy of faint planetary-mass companions to nearby stars is one of
the main challenges that new-generation high-contrast spectro-imagers are going
to face. In a previous work we presented a long slit coronagraph (LSC), for
which the presence of a slit in the coronagraphic focal plane induces a complex
distribution of energy in the Lyot pupil-plane that cannot be easily masked
with a binary Lyot stop. To alleviate this concern, we propose to use a pupil
apodization to suppress diffraction, creating an apodized long slit coronagraph
(ALSC). After describing how the apodization is optimized, we demonstrate its
advantages with respect to the CLC in the context of SPHERE/IRDIS long slit
spectroscopy (LSS) mode at low-resolution with a 0.12" slit and 0.18"
coronagraphic mask. We perform different sets of simulations with and without
aberrations, and with and without a slit to demonstrate that the apodization is
a more appropriate concept for LSS, at the expense of a significantly reduced
throughput (37%) compared to the LSC. Then we perform detailed end-to-end
simulations of the LSC and the ALSC that include realistic levels of
aberrations to obtain datasets representing 1h of integration time on stars of
spectral types A0 to M0 located at 10 pc. We insert spectra of planetary
companions at different effective temperatures (Teff) and surface gravities
(log g) into the data at angular separations of 0.3" to 1.5" and with contrast
ratios from 6 to 18 mag. Using the SD method to subtract the speckles, we show
that the ALSC brings a gain in sensitivity of up to 3 mag at 0.3" with respect
to the LSC, which leads to a much better spectral extraction below 0.5". In
terms of Teff, we demonstrate that at small angular separations the limit with
the ALSC is always lower by at least 100K, inducing an increase of sensitivity
of a factor up to 1.8 in objects' masses at young ages. [Abridged]Comment: 15 pages, 17 figures. Accepted for publication in A&
TERAFOR: DEXi-based multicriteria model for considering all multiple functions of tree formations in temperate agroforestry areas
info:eu-repo/semantics/publishedVersio
High-contrast spectroscopy of SCR J1845-6357 B
Spectral characterization of sub-stellar companions is essential to
understand their composition and formation processes. However, the large
contrast ratio of the brightness of each object to that of its parent star
limits our ability to extract a clean spectrum, free from any significant
contribution from the star. During the development of the long slit
spectroscopy (LSS) mode of IRDIS, the dual-band imager and spectrograph of
SPHERE, we proposed a data analysis method to estimate and remove the
contributions of the stellar spectrum. This method has never been tested on
real data because of the lack of instrumentation capable of combining adaptive
optics (AO), coronagraphy, and LSS. Nonetheless, a similar attenuation of the
star can be obtained using a particular observing configuration. Test data were
acquired using the AO-assisted spectrograph VLT/NACO. We obtained new J- and
H-band spectra of SCR J1845-6357 B, a T6 companion to a nearby (3.85\pm0.02 pc)
M8 star. This system is a well-suited benchmark as it is relatively wide
(~1.0") with a modest contrast ratio (~4 mag), and a previously published JHK
spectrum is available for reference. We demonstrate that (1) our method is
efficient at estimating and removing the stellar contribution, (2) it allows to
properly recover the spectral shape of the companion, and (3) it is essential
to obtain an unbiased estimation of physical parameters. We also show that the
slit configuration associated with this method allows us to use long exposure
times with high throughput producing high signal-to-noise ratio data. However,
the signal of the companion gets over-subtracted, particularly in our J-band
data, compelling us to use a fake companion spectrum to estimate and compensate
for the loss of flux. Finally, we report a new astrometric measurement of the
position of the companion (sep = 0.817", PA = 227.92 deg).Comment: 11 pages, 8 figures, 4 tables. Accepted for publication in A&
Early Results from VLT-SPHERE: Long-Slit Spectroscopy of 2MASS 0122-2439B, a Young Companion Near the Deuterium Burning Limit
We present 0.95-1.80 m spectroscopy of the 12-27
companion orbiting the faint (13.6), young (120 Myr) M-dwarf
2MASS J01225093--2439505 ("2M0122--2439 B") at 1.5 arcsecond separation (50
AU). Our coronagraphic long-slit spectroscopy was obtained with the new high
contrast imaging platform VLT-SPHERE during Science Verification. The unique
long-slit capability of SPHERE enables spectral resolution an order of
magnitude higher than other extreme AO exoplanet imaging instruments. With a
low mass, cool temperature, and very red colors, 2M0122-2439 B occupies a
particularly important region of the substellar color-magnitude diagram by
bridging the warm directly imaged hot planets with late-M/early-L spectral
types (e.g. Pic b and ROXs 42Bb) and the cooler, dusty objects near the
L/T transition (e.g. HR 8799bcde and 2MASS 1207b). We fit BT-Settl atmospheric
models to our 350 spectrum and find =1600100 K
and =4.50.5 dex. Visual analysis of our 2M0122-2439 B spectrum
suggests a spectral type L3-L4, and we resolve shallow -band alkali lines,
confirming its low gravity and youth. Specifically, we use the Allers & Liu
(2013) spectral indices to quantitatively measure the strength of the FeH, VO,
KI, spectral features, as well as the overall -band shape. Using these
indices, along with the visual spectral type analysis, we classify 2M0122-2439
B as an intermediate gravity (INT-G) object with spectral type L3.71.0.Comment: Accepted to ApJ Letters, 8 pages, 4 figures, some minor typographical
issues were fixe
Constraining the presence of giant planets in two-belt debris disk systems with VLT/SPHERE direct imaging and dynamical arguments
Giant, wide-separation planets often lie in the gap between multiple, distinct rings of circumstellar debris: this is the case for the HR 8799 and HD 95086 systems, and even the solar system where the Asteroid and Kuiper belts enclose the four gas and ice giants. In the case that a debris disk, inferred from an infrared excess in the SED, is best modelled as two distinct temperatures, we infer the presence of two spatially separated rings of debris. Giant planets may well exist between these two belts of debris, and indeed could be responsible for the formation of the gap between these belts. We observe 24 such two-belt systems using the VLT/SPHERE high contrast imager, and interpret our results under the assumption that the gap is indeed formed by one or more giant planets. A theoretical minimum mass for each planet can then be calculated, based on the predicted dynamical timescales to clear debris. The typical dynamical lower limit is ˜0.2MJ in this work, and in some cases exceeds 1MJ. Direct imaging data, meanwhile, is typically sensitive to planets down to ˜3.6MJ at 1", and 1.7MJ in the best case. Together, these two limits tightly constrain the possible planetary systems present around each target, many of which will be detectable with the next generation of high-contrast imagers
Constraining the mass of the planet(s) sculpting a disk cavity. The intriguing case of 2MASS J16042165-2130284
The large cavities observed in the dust and gas distributions of transition
disks may be explained by planet-disk interactions. At ~145 pc, 2MASS
J16042165-2130284 (J1604) is a 5-12 Myr old transitional disk with different
gap sizes in the mm- and m-sized dust distributions (outer edges at ~79
and at ~63 au, respectively). Its CO emission shows a ~30 au cavity.
This radial structure suggests that giant planets are sculpting this disk. We
aim to constrain the masses and locations of plausible giant planets around
J1604. We observed J1604 with the Spectro-Polarimetric High-contrast Exoplanet
REsearch (SPHERE) at the Very Large Telescope (VLT), in IRDIFS\_EXT,
pupil-stabilized mode, obtaining YJH- band images with the integral field
spectrograph (IFS) and K1K2-band images with the Infra-Red Dual-beam Imager and
Spectrograph (IRDIS). The dataset was processed exploiting the angular
differential imaging (ADI) technique with high-contrast algorithms. Our
observations reach a contrast of ~12 mag from 0.15" to 0.80"
(~22 to 115 au), but no planet candidate is detected. The disk is directly
imaged in scattered light at all bands from Y to K, and it shows a red color.
This indicates that the dust particles in the disk surface are mainly
m-sized grains. We confirm the sharp dip/decrement in
scattered light in agreement with polarized light observations. Comparing our
images with a radiative transfer model we argue that the southern side of the
disk is most likely the nearest. This work represents the deepest search yet
for companions around J1604. We reach a mass sensitivity of from ~22 to ~115 au according to a hot start scenario. We propose
that a brown dwarf orbiting inside of ~15 au and additional Jovian planets at
larger radii could account for the observed properties of J1604 while
explaining our lack of detection.Comment: 10 pages, 7 Figures. Accepted for publication in A&A . Abridged
abstrac
Combining observations from multiple platforms across the Kuroshio northeast of Luzon : a highlight on PIES data
Author Posting. © American Meteorological Society, 2016. This article is posted here by permission of American Meteorological Society for personal use, not for redistribution. The definitive version was published in Journal of Atmospheric and Oceanic Technology 33 (2016): 2185-2203, doi:10.1175/JTECH-D-16-0095.1.This study presents amended procedures to process and map data collected by pressure-sensor-equipped inverted echo sounders (PIESs) in western boundary current regions. The modifications to the existing methodology, applied to observations of the Kuroshio from a PIES array deployed northeast of Luzon, Philippines, consist of substituting a hydrography-based mean travel time field for the PIES-based mean field and using two distinct gravest empirical mode (GEM) lookup tables across the front that separate water masses of South China Sea and North Pacific origin. In addition, this study presents a method to use time-mean velocities from acoustic Doppler current profilers (ADCPs) to reference (or “level”) the PIES-recorded pressures in order to obtain time series of absolute geostrophic velocity. Results derived from the PIES observations processed with the hydrography-based mean field and two GEMs are compared with hydrographic profiles sampled by Seagliders during the PIES observation period and with current velocity measured concurrently by a collocated ADCP array. The updated processing scheme leads to a 41% error decrease in the determination of the thermocline depth across the current, a 22% error decrease in baroclinic current velocity shear, and a 61% error decrease in baroclinic volume transports. The absolute volume transport time series derived from the leveled PIES array compares well with that obtained directly from the ADCPs with a root-mean-square difference of 3.0 Sv (1 Sv ≡ 106 m3 s–1), which is mainly attributed to the influence of ageostrophic processes on the ADCP-measured velocities that cannot be calculated from the PIES observations.The authors are supported by the Office of Naval Research (ONR) Departmental Research Initiative entitled Origins of the Kuroshio and Mindanao Currents (ONR Grant N00014-10-1-0397). MA was supported by ONR Grants N00014-15-12593 and N00014-16-1-2668. CL was supported by ONR Grant N00014-10-0308. SJ was supported by MOST Grants NSC 101-2611-M-002-018-MY3, MOST 103-2611-M-002-011, and MOST 105-2119-M-002-042.2017-04-0
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