3,246 research outputs found
An Observational Diagnostic for Distinguishing Between Clouds and Haze in Hot Exoplanet Atmospheres
The nature of aerosols in hot exoplanet atmospheres is one of the primary
vexing questions facing the exoplanet field. The complex chemistry, multiple
formation pathways, and lack of easily identifiable spectral features
associated with aerosols make it especially challenging to constrain their key
properties. We propose a transmission spectroscopy technique to identify the
primary aerosol formation mechanism for the most highly irradiated hot Jupiters
(HIHJs). The technique is based on the expectation that the two key types of
aerosols -- photochemically generated hazes and equilibrium condensate clouds
-- are expected to form and persist in different regions of a highly irradiated
planet's atmosphere. Haze can only be produced on the permanent daysides of
tidally-locked hot Jupiters, and will be carried downwind by atmospheric
dynamics to the evening terminator (seen as the trailing limb during transit).
Clouds can only form in cooler regions on the night side and morning terminator
of HIHJs (seen as the leading limb during transit). Because opposite limbs are
expected to be impacted by different types of aerosols, ingress and egress
spectra, which primarily probe opposing sides of the planet, will reveal the
dominant aerosol formation mechanism. We show that the benchmark HIHJ,
WASP-121b, has a transmission spectrum consistent with partial aerosol coverage
and that ingress-egress spectroscopy would constrain the location and formation
mechanism of those aerosols. In general, using this diagnostic we find that
observations with JWST and potentially with HST should be able to distinguish
between clouds and haze for currently known HIHJs.Comment: 10 pages, 4 figures, accepted to ApJ Letter
Deciphering the Atmospheric Composition of WASP-12b: A Comprehensive Analysis of its Dayside Emission
WASP-12b was the first planet reported to have a carbon-to-oxygen ratio (C/O)
greater than one in its dayside atmosphere. However, recent work to further
characterize its atmosphere and confirm its composition has led to incompatible
measurements and divergent conclusions. Additionally, the recent discovery of
stellar binary companions ~1" from WASP-12 further complicates the analyses and
subsequent interpretations. We present a uniform analysis of all available
Hubble and Spitzer Space Telescope secondary-eclipse data, including
previously-unpublished Spitzer measurements at 3.6 and 4.5 microns. The primary
controversy in the literature has centered on the value and interpretation of
the eclipse depth at 4.5 microns. Our new measurements and analyses confirm the
shallow eclipse depth in this channel, as first reported by Campo and
collaborators and used by Madhusudhan and collaborators to infer a carbon-rich
composition. To explain WASP-12b's observed dayside emission spectrum, we
implemented several recent retrieval approaches. We find that when we exclude
absorption due to C2H2 and HCN, which are not universally considered in the
literature, our models require implausibly large atmospheric CO2 abundances,
regardless of the C/O. By including C2H2 and HCN in our models, we find that a
physically-plausible carbon-rich solution achieves the best fit to the
available photometric and spectroscopic data. In comparison, the best-fit
oxygen-rich models have abundances that are inconsistent with the chemical
equilibrium expectations for hydrogen-dominated atmospheres and are 670 times
less probable. Our best-fit solution is also 7.3*10^{6} times more probable
than an isothermal blackbody model.Comment: 8 pages, 7 figures, accepted for publication in Ap
C14 Automatic Imaging Telescope Photometry of GJ1214
GJ1214b is the highest signal-to-noise sub-Neptune for atmospheric studies.
Although most previous transmission spectroscopy measurements have revealed a
frustratingly featureless spectrum, JWST observations are expected to give new
insights to this benchmark planet. We have performed photometric monitoring of
GJ1214 (the host star) to provide context for these observations. We find that
GJ1214 entered a period of relatively high brightness during 2021 and 2022.
This implies that the JWST MIRI/LRS phase curve observation of GJ1214b in July
2022 was obtained during an epoch of low activity for the spot-dominated host
star. Like previous works, we are unable to definitively identify the star's
rotation period. Nevertheless, we confirm that it is likely >50 days.Comment: arXiv only posting, contact Greg Henry for access to the dat
Characterizing octagonal and rectangular fibers for MAROON-X
We report on the scrambling performance and focal-ratio-degradation (FRD) of
various octagonal and rectangular fibers considered for MAROON-X. Our
measurements demonstrate the detrimental effect of thin claddings on the FRD of
octagonal and rectangular fibers and that stress induced at the connectors can
further increase the FRD. We find that fibers with a thick, round cladding show
low FRD. We further demonstrate that the scrambling behavior of non-circular
fibers is often complex and introduce a new metric to fully capture non-linear
scrambling performance, leading to much lower scrambling gain values than are
typically reported in the literature (<1000 compared to 10,000 or more). We
find that scrambling gain measurements for small-core, non-circular fibers are
often speckle dominated if the fiber is not agitated.Comment: 10 pages, 8 figures, submitted to SPIE Advances in Optical and
Mechanical Technologies for Telescopes and Instrumentation 2016 (9912-185
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