46 research outputs found
Testing the Detectability of Extraterrestrial with the ELTs using Real Data with Real Noise
The future extremely large telescopes (ELTs) are expected to be powerful
tools to probe the atmospheres of extrasolar planets using high-dispersion
spectroscopy, with the potential to detect molecular oxygen in Earth-like
planets transiting nearby, late-type stars. So far, simulations have
concentrated on the optical 7600 \AA{} A-band of oxygen using synthetic noise
distributions. In this paper, we build upon previous work to predict the
detectability of molecular oxygen in nearby, temperate planets by using
archival, time-series data of Proxima Centauri from the high-dispersion UVES
spectrograph on ESO's Very Large Telescope (VLT). The brightest transiting
M-dwarfs are expected to be about 25 times fainter than Proxima, a factor that
is similar to the difference in light-gathering power between the VLT and the
future ELTs. By injecting synthetic oxygen transmission signals into the UVES
data, the detectability can be studied in the presence of real
data with real noise properties. Correcting for the relatively low throughput
(4%) of the Proxima spectra to an assumed 20% throughput for a
high-dispersion spectrograph on the European ELT, we find that the molecular
oxygen signature of an Earth-twin transiting a nearby () M5V star can be detected in 20-50 transits (a total of 70-175
hours of observing time). This estimate using more realistic simulations is
close to previous predictions. Novel concepts that increase the instrumental
throughput can further reduce the time span over which such observations need
to be taken.Comment: 7 pages, 6 figures, accepted for publication in ApJ
The orbital motion, absolute mass, and high-altitude winds of exoplanet HD209458b
For extrasolar planets discovered using the radial velocity method, the
spectral characterization of the host star leads to a mass-estimate of the star
and subsequently of the orbiting planet. In contrast, if also the orbital
velocity of the planet would be known, the masses of both star and planet could
be determined directly using Newton's law of gravity, just as in the case of
stellar double-line eclipsing binaries. Here we report on the detection of the
orbital velocity of extrasolar planet HD209458b. High dispersion ground-based
spectroscopy during a transit of this planet reveals absorption lines from
carbon monoxide produced in the planet atmosphere, which shift significantly in
wavelength due to the change in the radial component of the planet orbital
velocity. These observations result in a mass determination of the star and
planet of 1.00+-0.22 Msun and 0.64+-0.09 Mjup respectively. A ~2 km/sec
blueshift of the carbon monoxide signal with respect to the systemic velocity
of the host star suggests the presence of a strong wind flowing from the
irradiated dayside to the non-irradiated nightside of the planet within the
0.01-0.1 mbar atmospheric pressure range probed by these observations. The
strength of the carbon monoxide signal suggests a CO mixing ratio of 1-3x10-3
in this planet's upper atmosphere.Comment: 11 Pages main article and 6 pages suppl. information: A final, edited
version appears in the 24 May 2010 issue of Natur
Detection of carbon monoxide in the high-resolution day-side spectrum of the exoplanet HD 189733b
[Abridged] After many attempts over more than a decade, high-resolution
spectroscopy has recently delivered its first detections of molecular
absorption in exoplanet atmospheres, both in transmission and thermal emission
spectra. Targeting the combined signal from individual lines in molecular
bands, these measurements use variations in the planet radial velocity to
disentangle the planet signal from telluric and stellar contaminants. In this
paper we apply high resolution spectroscopy to probe molecular absorption in
the day-side spectrum of the bright transiting hot Jupiter HD 189733b. We
observed HD 189733b with the CRIRES high-resolution near-infrared spectograph
on the Very Large Telescope during three nights. We detect a 5-sigma absorption
signal from CO at a contrast level of ~4.5e-4 with respect to the stellar
continuum, revealing the planet orbital radial velocity at 154+4/-3 km s-1.
This allows us to solve for the planet and stellar mass in a similar way as for
stellar eclipsing binaries, resulting in Ms= 0.846+0.068/-0.049 Msun and Mp=
1.162+0.058/-0.039 MJup. No significant absorption is detected from H2O, CO2 or
CH4 and we determined upper limits on their line contrasts here. The detection
of CO in the day-side spectrum of HD 189733b can be made consistent with the
haze layer proposed to explain the optical to near-infrared transmission
spectrum if the layer is optically thin at the normal incidence angles probed
by our observations, or if the CO abundance is high enough for the CO
absorption to originate from above the haze. Our non-detection of CO2 at 2.0
micron is not inconsistent with the deep CO2 absorption from low resolution
NICMOS secondary eclipse data in the same wavelength range. If genuine, the
absorption would be so strong that it blanks out any planet light completely in
this wavelength range, leaving no high-resolution signal to be measured.Comment: A&A, accepted for publication. Fig.1 reduced in qualit
Spectroscopic Transit Search: a self-calibrating method for detecting planets around bright stars
We search for transiting exoplanets around the star Pictoris using
high resolution spectroscopy and Doppler imaging that removes the need for
standard star observations. These data were obtained on the VLT with UVES
during the course of an observing campaign throughout 2017 that monitored the
Hill sphere transit of the exoplanet Pictoris b. We utilize line
profile tomography as a method for the discovery of transiting exoplanets. By
measuring the exoplanet distortion of the stellar line profile, we remove the
need for reference star measurements. We demonstrate the method with white
noise simulations, and then look at the case of Pictoris, which is a
Scuti pulsator. We describe a method to remove the stellar pulsations
and perform a search for any transiting exoplanets in the resultant data set.
We inject fake planet transits with varying orbital periods and planet radii
into the spectra and determine the recovery fraction. In the photon noise
limited case we can recover planets down to a Neptune radius with an 80%
success rate, using an 8 m telescope with a spectrograph and 20
minutes of observations per night. The pulsations of Pictoris limit our
sensitivity to Jupiter-sized planets, but a pulsation removal algorithm
improves this limit to Saturn-sized planets. We present two planet candidates,
but argue that their signals are most likely caused by other phenomena. We have
demonstrated a method for searching for transiting exoplanets that (i) does not
require ancillary calibration observations, (ii) can work on any star whose
rotational broadening can be resolved with a high spectral dispersion
spectrograph and (iii) provides the lowest limits so far on the radii of
transiting Jupiter-sized exoplanets around Pictoris with orbital
periods from 15 days to 200 days with >50% coverage.Comment: Accepted for publication in A&A, 8 pages, 8 figures. The Github
repository can be found at
https://github.com/lennartvansluijs/Spectroscopic-Transit-Searc
No Massive Companion to the Coherent Radio-Emitting M Dwarf GJ 1151
The recent detection of circularly polarized, long-duration (>8 hr)
low-frequency (~150 MHz) radio emission from the M4.5 dwarf GJ 1151 has been
interpreted as arising from a star-planet interaction via the electron
cyclotron maser instability. The existence or parameters of the proposed
planets have not been determined. Using 20 new HARPS-N observations, we put
99th-percentile upper limits on the mass of any close companion to GJ 1151 at
Msini < 5.6 M earth. With no stellar, brown dwarf, or giant planet companion
likely in a close orbit, our data are consistent with detected radio emission
emerging from a magnetic interaction between a short-period terrestrial-mass
planet and GJ 1151
Search for Rayleigh scattering in the atmosphere of GJ1214b
We investigate the atmosphere of GJ1214b, a transiting super-Earth planet
with a low mean density, by measuring its transit depth as a function of
wavelength in the blue optical portion of the spectrum. It is thought that this
planet is either a mini-Neptune, consisting of a rocky core with a thick,
hydrogen-rich atmosphere, or a planet with a composition dominated by water.
Most observations favor a water-dominated atmosphere with a small scale-height,
however, some observations indicate that GJ1214b could have an extended
atmosphere with a cloud layer muting the molecular features. In an atmosphere
with a large scale-height, Rayleigh scattering at blue wavelengths is likely to
cause a measurable increase in the apparent size of the planet towards the
blue. We observed the transit of GJ1214b in the B-band with the FOcal Reducing
Spectrograph (FORS) at the Very Large Telescope (VLT) and in the g-band with
both ACAM on the William Hershel Telescope (WHT) and the Wide Field Camera
(WFC) at the Isaac Newton Telescope (INT). We find a planet-to-star radius
ratio in the B-band of 0.1162+/-0.0017, and in the g-band 0.1180+/-0.0009 and
0.1174+/-0.0017 for the WHT & INT observations respectively. These optical data
do not show significant deviations from previous measurements at longer
wavelengths. In fact, a flat transmission spectrum across all wavelengths best
describes the combined observations. When atmospheric models are considered a
small scale-height water-dominated model fits the data best.Comment: Accepted for publication in Ap
Transmission spectroscopy of the ultra-hot Jupiter MASCARA-4 b: Disentangling the hydrostatic and exospheric regimes of ultra-hot Jupiters
Ultra-hot Jupiters (UHJs), rendering the hottest planetary atmospheres, offer
great opportunities of detailed characterisation with high-resolution
spectroscopy. MASCARA-4 b is a recently discovered close-in gas giant belonging
to this category. In order to refine system and planet parameters, we carried
out radial velocity measurements and transit photometry with the CORALIE
spectrograph and EulerCam at the Swiss 1.2m Euler telescope. We observed two
transits of MASCARA-4 b with the high-resolution spectrograph ESPRESSO at ESO's
Very Large Telescope. We searched for atomic, ionic, and molecular species via
individual absorption lines and cross-correlation techniques. These results are
compared to literature studies on UHJs characterised to date. With CORALIE and
EulerCam observations, we updated the mass of MASCARA-4 b (1.675 +/- 0.241
Jupiter masses) as well as other system and planet parameters. In the
transmission spectrum derived from ESPRESSO observations, we resolve excess
absorption by H, H, Na D1 & D2, Ca+ H & K, and a few strong
individual lines of Mg, Fe and Fe+. We also present the cross-correlation
detection of Mg, Ca, Cr, Fe and Fe+. The absorption strength of Fe+
significantly exceeds the prediction from a hydrostatic atmospheric model, as
commonly observed in other UHJs. We attribute this to the presence of Fe+ in
the exosphere due to hydrodynamic outflows. This is further supported by the
positive correlation of absorption strengths of Fe+ with the H line.
Comparing transmission signatures of various species in the UHJ population
allows us to disentangle the hydrostatic regime (as traced via the absorption
by Mg and Fe) from the exospheres (as probed by H and Fe+) of the
strongly irradiated atmospheres.Comment: 13 pages, 9 figures, accepted to A&
Misaligned spin and orbital axes cause the anomalous precession of DI Herculis
The orbits of binary stars precess as a result of general relativistic
effects, forces arising from the asphericity of the stars, and forces from
additional stars or planets in the system. For most binaries, the theoretical
and observed precession rates are in agreement. One system, however -- DI
Herculis -- has resisted explanation for 30 years. The observed precession rate
is a factor of four slower than the theoretical rate, a disagreement that once
was interpreted as evidence for a failure of general relativity. Among the
contemporary explanations are the existence of a circumbinary planet and a
large tilt of the stellar spin axes with respect to the orbit. Here we report
that both stars of DI Herculis rotate with their spin axes nearly perpendicular
to the orbital axis (contrary to the usual assumption for close binary stars).
The rotationally induced stellar oblateness causes precession in the direction
opposite to that of relativistic precession, thereby reconciling the
theoretical and observed rates.Comment: Nature, in press [11 pg