Your search keyword '"Pérez-Hoyos S"' showing total 18 results

1. Assessing Multi‐Stream Radiative Transfer Schemes for the Calculation of Aerosol Radiative Forcing in the Martian Atmosphere.

Author

Chen‐Chen, H., Pérez‐Hoyos, S., and Sánchez‐Lavega, A.

Subjects

MARTIAN atmosphere, SOLAR radiation, ATMOSPHERIC circulation, AEROSOLS, RADIATIVE transfer

Abstract

The atmosphere of Mars presents a strong response to aerosol radiative forcing compared to that of the Earth, thus atmospheric models should have accurate radiative transfer algorithms for the simulation of temperatures and circulation. In this work, we evaluate the radiative effects of dust aerosol calculated by different radiative transfer schemes and the influence of dust properties in these calculations. Two‐stream solutions were compared with multistream discrete ordinate methods. Fluxes and heating rates were evaluated for a variety of atmospheric conditions, including dust storms. The results show that in low‐to‐medium dust opacity scenarios, the highly efficient two‐stream methods provide accurate estimations, with heating rate errors of less than 2 K/sol. These errors increase with opacity, when differences of 20 K/sol are reached, which may be relevant in the simulations of temperature fields and atmospheric circulation under regional and global dust storm conditions. In such cases, the use of four‐stream or higher order methods may be required, although accuracy improvements for eight‐ or higher‐stream schemes were negligible. The influence of dust particle properties in aerosol radiative forcing estimations is mainly due to the particle size, where variations of 20% of the effective radius resulted in differences of 5 K/sol; the shape of the particles showed a minor impact, with differences of <2 K/sol. The results of this study contribute to quantification of the uncertainties in current Mars climate models and may help modellers to select the appropriate approach depending on the scenario. Plain Language Summary: The thin atmosphere of Mars has a strong response to the effects of dust aerosol compared to that of the Earth. The radiative heating and cooling due to dust affect the temperatures and drive the Martian climate at all spatial scales. In addition, remote sensing retrievals and studies of climate and weather on Mars depend on precise calculations of these quantities. The "two‐stream" method for calculating the energy budget and temperature variations is widely used, although it presents some limitations in modeling dust interactions with solar radiation. In this work, we compare radiative estimations of this method with results obtained by more accurate, but time consuming, algorithms. The comparison results show a good agreement when there is low to medium amount of lofted dust. As the atmospheric dust loading increases, such as in the case of regular Mars dust storms, more complex methods may be required. Regarding the influence of dust particle properties in these calculations, the uncertainties associated with the size of the particles introduce meaningful differences at high altitudes. The results of this study contribute to quantification of the uncertainties in Mars climate models and may help modellers to select the appropriate method depending on the scenario. Key Points: We study the accuracy and performance of radiative transfer schemes of Mars' atmosphere and the impact of dust aerosol particle propertiesTwo‐stream approximations provide accurate radiative flux and heating rate estimates in low and medium opacity scenariosIn high opacity cases and dust storms, four‐stream methods may be recommended. Accuracy improvements from higher‐order methods are negligible [ABSTRACT FROM AUTHOR]

Published

2021

2. Multilayer hazes over Saturn's hexagon from Cassini ISS limb images.

Author

Sánchez-Lavega, A., García-Muñoz, A., del Río-Gaztelurrutia, T., Pérez-Hoyos, S., Sanz-Requena, J. F., Hueso, R., Guerlet, S., and Peralta, J.

Subjects

GRAVITY waves, HAZE, INTERNAL waves, HEXAGONS, RADIATIVE transfer, ALTITUDES

Abstract

In June 2015, Cassini high-resolution images of Saturn's limb southwards of the planet's hexagonal wave revealed a system of at least six stacked haze layers above the upper cloud deck. Here, we characterize those haze layers and discuss their nature. Vertical thickness of layers ranged from 7 to 18 km, and they extended in altitude ∼130 km, from pressure level 0.5 bar to 0.01 bar. Above them, a thin but extended aerosol layer reached altitude ∼340 km (0.4 mbar). Radiative transfer modeling of spectral reflectivity shows that haze properties are consistent with particles of diameter 0.07–1.4 μm and number density 100–500 cm−3. The nature of the hazes is compatible with their formation by condensation of hydrocarbon ices, including acetylene and benzene at higher altitudes. Their vertical distribution could be due to upward propagating gravity waves generated by dynamical forcing by the hexagon and its associated eastward jet. The authors analyze a system of multi-layered hazes above Saturn's hexagonal-wave cloud tops in the visual range. Analyses suggest the formation to be caused by condensation processes, and the vertical distribution of stacked layers by the upward propagation of internal gravity waves. [ABSTRACT FROM AUTHOR]

Published

2020

3. Hazes and clouds in a singular triple vortex in Saturn's atmosphere from HST/WFC3 multispectral imaging.

Author

Sanz-Requena, J.F., Pérez-Hoyos, S., Sánchez-Lavega, A., del Rio-Gaztelurrutia, T., and Irwin, Patrick G.J.

Subjects

*HAZE, *MULTISPECTRAL imaging, *ATMOSPHERE

Abstract

In this paper we present a study of the vertical haze and cloud structure over a triple vortex in Saturn's atmosphere in the planetographic latitude range 55°N-69°N (del Río-Gaztelurrutia et al., 2018) using HST/WFC3 multispectral imaging. The observations were taken during 29–30 June and 1 July 2015 at ten different filters covering spectral range from the 225 nm to 937 nm, including the deep methane band at 889 nm. Absolute reflectivity measurements of this region at all wavelengths and under a number of illumination and observation geometries are fitted with the values produced by a radiative transfer model. Most of the reflectivity variations in this wavelength range can be attributed to changes in the tropospheric haze. The anticyclones are optically thicker (τ ~25 vs ~10), more vertically extended (~3 gas scale heights vs ~2) and their bases are located deeper in the atmosphere (550 mbar vs 500 mbar) than the cyclone. • We present the cloud and haze structure in a triple vortex in Saturn's atmosphere. • Most of the reflectivity changes are related to the properties of the tropospheric haze. • In the anticyclonic region we find a higher particle number density than in the cyclonic region • The aerosol optical thickness and vertical extent agree with upwelling in the anticyclones. [ABSTRACT FROM AUTHOR]

Published

2019

4. Haze and cloud structure of Saturn's North Pole and Hexagon Wave from Cassini/ISS imaging.

Author

Sanz-Requena, J.F., Pérez-Hoyos, S., Sánchez-Lavega, A., Antuñano, A., and Irwin, Patrick G.J.

Subjects

*ATMOSPHERIC circulation, *STRATOSPHERE, *IMAGING systems, *RADIATIVE transfer, *PARTICLE size distribution

Abstract

In this paper we present a study of the vertical haze and cloud structure in the upper two bars of Saturn's Northern Polar atmosphere using the Imaging Science Subsystem (ISS) instrument onboard the Cassini spacecraft. We focus on the characterization of latitudes from 53° to 90° N. The observations were taken during June 2013 with five different filters (VIO, BL1, MT2, CB2 and MT3) covering spectral range from the 420 nm to 890 nm (in a deep methane absorption band). Absolute reflectivity measurements of seven selected regions at all wavelengths and several illumination and observation geometries are compared with the values produced by a radiative transfer model. The changes in reflectivity at these latitudes are mostly attributed to changes in the tropospheric haze. This includes the haze base height (from 600 ± 200 mbar at the lowest latitudes to 1000 ± 300 mbar in the pole), its particle number density (from 20 ± 2 particles/cm 3 to 2 ± 0.5 particles/cm 3 at the haze base) and its scale height (from 18 ± 0.1 km to 50 ± 0.1 km). We also report variability in the retrieved particle size distribution and refractive indices. We find that the Hexagonal Wave dichotomizes the studied stratospheric and tropospheric hazes between the outer, equatorward regions and the inner, Polar Regions. This suggests that the wave or the jet isolates the particle distribution at least at tropospheric levels. [ABSTRACT FROM AUTHOR]

Published

2018

5. Venus Upper Clouds and the UV Absorber From MESSENGER/MASCS Observations.

Author

Pérez‐Hoyos, S., Sánchez‐Lavega, A., García‐Muñoz, A., Irwin, P. G. J., Peralta, J., Holsclaw, G., McClintock, W. M., and Sanz‐Requena, J. F.

Abstract

Abstract: One of the most intriguing, long‐standing questions regarding Venus's atmosphere is the origin and distribution of the unknown UV absorber, responsible for the absorption band detected at the near‐UV and blue range of Venus's spectrum. In this work, we use data collected by Mercury Atmospheric and Surface Composition Spectrometer (MASCS) spectrograph on board the MErcury Surface, Space ENvironment, GEochemistry, and Ranging (MESSENGER) mission during its second Venus flyby in June 2007 to address this issue. Spectra range from 0.3 μm to 1.5 μm including some gaseous H2O and CO2 bands, as well as part of the SO2 absorption band and the core of the UV absorption. We used the NEMESIS radiative transfer code and retrieval suite to investigate the vertical distribution of particles in the equatorial atmosphere and to retrieve the imaginary refractive indices of the UV absorber, assumed to be well mixed with Venus's small mode 1 particles. The results show a homogeneous equatorial atmosphere, with cloud tops (height for unity optical depth) at 75 ± 2 km above surface. The UV absorption is found to be centered at 0.34 ± 0.03 μm with a full width at half maximum of 0.14 ± 0.01 μm. Our values are compared with previous candidates for the UV aerosol absorber, among which disulfur oxide (S2O) and dioxide disulfur (S2O2) provide the best agreement with our results. [ABSTRACT FROM AUTHOR]

Published

2018

6. Glory revealed in disk-integrated photometry of Venus.

Author

García Muñoz, A., Pérez-Hoyos, S., and Sánchez-Lavega, A.

Subjects

*RADIATIVE transfer, *VENUS planet research, *ASTRONOMICAL photometry, *SPECTRA of Venus planet, *VENUSIAN atmosphere, *CLOUD droplets, *DISKS (Astrophysics)

Abstract

Context. Reflected light from a spatially unresolved planet yields unique insight into the overall optical properties of the planet cover. Glories are optical phenomena caused by light that is backscattered within spherical droplets following a narrow distribution of sizes; they are well known on Earth as localised features above liquid clouds. Aims. Here we report the first evidence for a glory in the disk-integrated photometry of Venus and, in turn, of any planet. Methods. We used previously published phase curves of the planet that were reproduced over the full range of phase angles with model predictions based on a realistic description of the Venus atmosphere. We assumed that the optical properties of the planet as a whole can be described by a uniform and stable cloud cover, an assumption that agrees well with observational evidence. Results. We specifically show that the measured phase curves mimic the scattering properties of the Venus upper-cloud micron-sized aerosols, also at the small phase angles at which the glory occurs, and that the glory contrast is consistent with what is expected after multiple scattering of photons. In the optical, the planet appears to be brighter at phase angles of ~11-13° than at full illumination; it undergoes a maximum dimming of up to ~10% at phases in between. Conclusions. Glories might potentially indicate spherical droplets and, thus, extant liquid clouds in the atmospheres of exoplanets. A prospective detection will require exquisite photometry at the small planet-star separations of the glory phase angles. [ABSTRACT FROM AUTHOR]

Published

2014

7. Cloud structure of Saturn’s 2010 storm from ground-based visual imaging

Author

Sanz-Requena, J.F., Pérez-Hoyos, S., Sánchez-Lavega, A., del Río-Gaztelurrutia, T., Barrado-Navascués, D., Colas, F., Lecacheux, J., and Parker, D.

Subjects

*RADIATIVE transfer, *OZONE layer, *TROPOSPHERIC aerosols, *NEAR infrared radiation, *ASTROPHYSICS, *SATURN (Planet)

Abstract

Abstract: We present a study of the vertical cloud structure for the initial stage of the Great White Spot (GWS), a giant storm that developed in Saturn in December 2010, using ground-based visual images. We focus in the characterization of the undisturbed atmosphere preceding the storm and the disturbed region in the wake of the GWS. The observations were taken at Calar Alto (Spain) and Pic du Midi (France) observatories on 27 December 2010 and 13 January 2011, about 1month after the detection of the outbreak. They cover a spectral range from the ultraviolet at 375nm to the near infrared at 954nm, including the deep methane absorption band at 890nm and a number of increasingly weaker methane absorption bands. Limb to limb scans of the absolute reflectivity of the regions preceding and following the storm at different wavelengths are compared to those produced by a radiative transfer model atmosphere. Our model assumes three layers of gas and particles: stratospheric and tropospheric hazes and a deep cloud. We find that the most notorious changes in the wake of the GWS occurred in the top level of the semi-infinite bottom cloud which ascended from an altitude level P >1bar in the undisturbed region to in the stormy area, representing a rise of more than 40km. The density of the tropospheric haze does not change substantially but tropospheric particles are found to be more reflectant at all wavelengths, suggesting that they are coated by fresh material, putatively coming from deeper levels of the atmosphere. [Copyright &y& Elsevier]

Published

2012

8. The 2009–2010 fade of Jupiter’s South Equatorial Belt: Vertical cloud structure models and zonal winds from visible imaging

Author

Pérez-Hoyos, S., Sanz-Requena, J.F., Barrado-Izagirre, N., Rojas, J.F., and Sánchez-Lavega, A.

Subjects

*ZONAL winds, *WAVELENGTHS, *ALBEDO, *ASTRONOMICAL observations, *IMAGING systems, *JUPITER (Planet)

Abstract

Abstract: The South Equatorial Belt (SEB) of Jupiter is known to alternate its appearance at visible wavelengths from a classical belt-like band most of the time to a short-lived zone-like aspect which is called a “fade” of the belt, hereafter SEBF. The albedo change of the SEB is due to a change in the structure and properties of the clouds and upper hazes. Recent works based on infrared observations of the last SEBF have shown that the aerosol density below 1bar increased in parallel with the reflectivity change. However, the nature of the change in the upper clouds and hazes that produces the visible reflectivity change and whether or not this reflectivity change is accompanied by a change in the winds at the upper cloud level remained unknown. In this paper we focus in the near ultraviolet to near infrared reflected sunlight (255–953nm) to address these two issues. We characterize the vertical cloud structure above the ammonia condensation level from Hubble Space Telescope images, and the zonal wind velocities from long-term high-quality images coming from the International Outer Planet Watch database, both during the SEB and SEBF phases. We show that reflectivity changes do not happen simultaneously in this wavelength range, but they start earlier in the most deep-sensing filters and end in 2010 with just minor changes in those sensing the highest particle layers. Our models require a substantial increase of the optical thickness of the cloud deck at 1.0±0.4bar from τcloud =6±2 in July 2009 (SEB phase) to semiinfinite at visual wavelengths in 2010 (SEBF). Upper tropospheric particles (∼240–1400mbar) are also required to become substantially reflectant and their single scattering albedo in the blue changes from ϖ 0 =0.905±0.005 in November 2009 to ϖ 0 =0.95±0.01 in June 2010. No significant changes were found in the cloud top heights or in the particle density of the tropospheric haze. The disturbance travels from the levels below ∼3bar to a level about 400±100mbar. We derive an upward velocity of 0.15±0.05cm/s, in agreement with a diffusive process in Jupiter’s upper troposphere requiring a mean eddy coefficient K ∼8×105 cm2 s−1. On the other hand, cloud tracking on the IOPW imaging showed no significant changes in the zonal wind profile between the SEB and SEBF stages. As in other visually huge changes in Jupiter’s cloud morphology and structure, the wind profile remains robust, possibly indicating a deeply rooted dynamical regime. [Copyright &y& Elsevier]

Published

2012

9. The jovian anticyclone BA: III. Aerosol properties and color change

Author

Pérez-Hoyos, S., Sánchez-Lavega, A., Hueso, R., García-Melendo, E., and Legarreta, J.

Subjects

*ANTICYCLONES, *AEROSOLS, *CYCLONES, *ULTRAVIOLET radiation, *REFRACTIVE index, *ATMOSPHERE of Jupiter, *JUPITER (Planet)

Abstract

Abstract: A study of the vertical cloud structure of oval BA and its red color change is presented in this third part of our complete analysis. A large interest in Jupiter’s anticyclone BA was created by its reddening that occurred between 2005 and 2006. In this work we quantify the color change in oval BA by using images taken with the Advanced Camera for Surveys (ACS) onboard the Hubble Space Telescope (HST) in six filters from the near ultraviolet (F250W) to the deep methane band in the near infrared (F892N). Reflectivity changes are noteworthy in nadir viewing geometry at the ultraviolet and blue wavelengths (F250W, F330W and F435W filters) but almost undetectable or inside error bars in the rest of filters (F550M, F658N and F892N). The observed reflectivity variations are discussed in terms of a commonly accepted vertical cloud structure model for jovian anticyclones in order to explore some causes for the color alteration. Our models of the observed reflectivity variation show that the vortex clouds did not change its vertical extension (top pressure) or its optical depth. We find that a change occurred in the absorbing properties of the particles populating the upper aerosols (single scattering albedo and imaginary refractive index). A discussion on the thermo-physical and dynamical properties of the vortex that could be in the origin of the color change is also presented. [Copyright &y& Elsevier]

Published

2009

10. Solar flux in Saturn's atmosphere: Penetration and heating rates in the aerosol and cloud layers

Author

Pérez-Hoyos, S. and Sánchez-Lavega, A.

Subjects

*SOLAR radiation, *SATURN (Planet), *AEROSOLS, *SOLAR heating

Abstract

Abstract: In this work, we describe an analysis of the internal solar radiation fields in Saturn''s atmosphere. The aim of this paper is to study how the solar radiation flux in optical wavelengths (0.25–1.0 μm) is attenuated, primarily by the effect of the aerosols located close to the tropopause level, retrieving also the corresponding solar heating rates. We use a doubling–adding method and previous results on the vertical cloud and haze structure of Saturn''s atmosphere. Our study shows that the maximum penetration level (∼250 mbar) for these wavelengths is substantially higher than previously expected because of the huge optical thickness of the tropospheric haze described in all vertical cloud structure models. We compare our results with previous estimates and parameterizations for seasonal climate models and propose a new approach for future models, with an intense and concentrated heating rate close to the top level of the tropospheric haze. Given that our spectral range accounts for about the 70% of the total solar flux, and using previous estimates for the penetration levels of infrared radiation in Saturn''s atmosphere, we conclude solar radiation effect is negligible at levels below 600 mbar. This result is fundamental for understanding the role of solar radiation in the general atmospheric circulation of Saturn. [Copyright &y& Elsevier]

Published

2006

11. On the vertical wind shear of Saturn's Equatorial Jet at cloud level

Author

Pérez-Hoyos, S. and Sánchez-Lavega, A.

Subjects

*SATURN (Planet), *WIND shear, *ATMOSPHERE, *ORBITS (Astronomy)

Abstract

Abstract: In this work we analyze and compare the vertical cloud structure of Saturn''s Equatorial Zone in two different epochs: the first one close to the Voyagers flybys (1979–1981) and the second one in 2004, when the Cassini spacecraft entered its orbit around the planet. Our goal is to retrieve the altitude of cloud features used as zonal wind tracers in both epochs. We reanalyze three different sets of photometrically calibrated published data: ground-based in 1979, Voyager 2 PPS and ISS observations in 1981, and we analyze a new set of Hubble Space Telescope images for 2004. For all situations we reproduced the observed reflectivity by means of a similar vertical model with three layers. The results indicate the presence of a changing tropospheric haze in 1979–1981 (, ) and in 2004 (, ) where the tracers are embedded. According to this model the Voyager 2 ISS images locate cloud tracers moving with zonal velocities of 455 to 465 (±2) m/s at a pressure level of 360±140 mbar. For HST observations, our previous works had showed cloud tracers moving with zonal wind speeds of at a pressure level of about . All these values are calculated in the same region (). This speed difference, if interpreted as a vertical wind shear, requires a change of per scale height, two times greater than that estimated from temperature observations. We also perform an initial guess on Cassini ISS vertical sounding levels, retrieving values compatible with HST ones and Cassini CIRS derived vertical wind shear, but not with Voyager wind measurements. We conclude that the wind speed velocity differences measured between 1979–1981 and 2004 cannot be explained as a wind shear effect alone and demand dynamical processes. [Copyright &y& Elsevier]

Published

2006

12. Saturn's cloud structure and temporal evolution from ten years of Hubble Space Telescope images (1994–2003)

Author

Pérez-Hoyos, S., Sánchez-Lavega, A., French, R.G., and Rojas, J.F.

Subjects

*TELESCOPES, *ASTRONOMICAL instruments, *HAZE, *METEOROLOGICAL optics

Abstract

Abstract: We present a study of the vertical structure of clouds and hazes in the upper atmosphere of Saturn''s Southern Hemisphere during 1994–2003, about one third of a Saturn year, based on Hubble Space Telescope images. The photometrically calibrated WFPC2 images cover the spectral region between the near-UV (218–255 nm) and the near-IR (953–1042 nm), including the 890 nm methane band. Using a radiative transfer code, we have reproduced the observed center-to-limb variations in absolute reflectivity at selected latitudes which allowed us to characterize the vertical structure of the entire hemisphere during this period. A model atmosphere with two haze layers has been used to study the variation of hazes with latitude and to characterize their temporal changes. Both hazes are located above a thick cloud, putatively composed of ammonia ice. An upper thin haze in the stratosphere (between 1 and 10 mbar) is found to be persistent and formed by small particles (radii ). The lower thicker haze close to the tropopause level shows a strong latitudinal dependence in its optical thickness (typically τ∼20–40 at the equator but τ∼5 at the pole, at 814 nm). This tropospheric haze is blue-absorbent and extends from 50 to 100 mbar to about ∼400 mbar. Both hazes show temporal variability, but at different time-scales. First, there is a tendency for the optical thickness of the stratospheric haze to increase at all latitudes as insolation increases. Second, the tropospheric haze shows mid-term changes (over time scales from months to 1–2 years) in its optical thickness (typically by a factor of 2). Such changes always occur within a rather narrow latitude band (width ∼5–10°), affecting almost all latitudes but at different times. Third, we detected a long-term (∼10 year) decrease in the blue single-scattering albedo of the tropospheric haze particles, most intense in the equatorial and polar areas. Long-term changes follow seasonal insolation variations smoothly without any apparent delay, suggesting photochemical processes that affect the particles optical properties as well as their size. In contrast, mid-term changes are sudden and show various time-scales, pointing to a dynamical origin. [Copyright &y& Elsevier]

Published

2005

13. Color and aerosol changes in Jupiter after a North Temperate Belt disturbance.

Author

Pérez-Hoyos, S., Sánchez-Lavega, A., Sanz-Requena, J.F., Barrado-Izagirre, N., Carrión-González, O., Anguiano-Arteaga, A., Irwin, P.G.J., and Braude, A.S.

Subjects

*ATMOSPHERE of Jupiter, *ATMOSPHERIC ammonia, *REFRACTIVE index, *AEROSOLS, *RADIATIVE transfer, *OPTICAL properties

Abstract

The banded appearance of Jupiter's atmosphere shows significant changes over time, sometimes even transforming the reflectivity of a whole latitudinal band in a few weeks, and staying for years with an aspect different from the usual one. The origin of some of these disturbances may be associated with the creation and destruction of the chromophore species that provides Jovian clouds their reddish coloration. In this work, we have focused on the North Temperate Belt (NTB) disturbance detected during the second flyby of Juno mission (NASA) on October 2016, as a series of convective storms interacted with the fastest zonal jet on Jupiter at 24 ∘ N over months and left a quiet belt characterized by an intense red coloration Sánchez-Lavega et al. (2017). In order to determine the corresponding changes in the upper clouds and hazes we have used images taken in 2016 and 2017 with the Hubble Space Telescope Wide Field Camera 3. Such images were acquired before and after the outbreak, showing an intense color change in a narrow latitude band. The images cover the wavelength range from 250 nm up to the methane absorption band at 890 nm, thus sensitive to a number of atmospheric levels from the lower stratosphere to the upper troposphere where the ammonia condensation cloud is expected to be located. Here we use the radiative transfer suite NEMESIS Irwin et al. (2008) to determine the vertical distribution and properties of the upper hazes that best match the observed dependence of reflectivity with wavelength and geometry. We use two models for the Jovian chromophore: (A) an extended layer whose imaginary refractive index is left as a free parameter; and (B) a concentrated chromophore as in Sromovsky et al. (2017) using the optical properties by Carlson et al. (2016). Both scenarios show an increase in the number of particles responsible for the blue absorption approximately by a factor of 2, and require only small changes in the rest of the atmospheric parameters. We find that, even though results provided by scenario B are also compatible with observations, the limb-darkening is better described by scenario A, where there is also an increase of the particle absorption at the shortest wavelengths. In this work, we also provide an extension of the expected imaginary refractive indices to wavelengths beyond those covered in previous laboratory works, which will be useful for future studies. • We model the reflectivity change of Jupiter's NTB in 2016 and 2017. • A chromophore well mixed within the tropospheric haze better reproduces the observed limb-darkening. • The disturbance changed the particle concentration at upper tropospheric levels. [ABSTRACT FROM AUTHOR]

Published

2020

14. Jupiter's polar clouds and waves from Cassini and HST images: 1993–2006

Author

Barrado-Izagirre, N., Sánchez-Lavega, A., Pérez-Hoyos, S., and Hueso, R.

Subjects

*ATMOSPHERE, *OUTER planets, *HEAT radiation & absorption, *JUPITER (Planet), *GAS giants

Abstract

Abstract: For a variety of reasons, Jupiter''s polar areas are probably the less observed regions of the planet. To study the dynamics and cloud vertical structure in the polar regions of the planet (latitudes 50° to 80° in both hemispheres) we have used images of Jupiter obtained from the ultraviolet to near infrared (258 to 939 nm) by the Cassini Imagining Science Subsystem (ISS) in December 2000. The temporal coverage was complemented with archived images from the Hubble Space Telescope (1993–2006) in a similar spectral range. The zonal wind velocities have been measured at three Cassini ISS wavelengths (CB2, MT3 and UV1, corresponding to 750, 890 and 258 nm) sounding different altitude levels. The three eastward jets detected in CB2 images (lower cloud) go to zero velocity when measured in the UV1 filter (upper haze). A radiative transfer analysis has been performed to characterize the vertical structure of cloud and hazes distribution at the poles. We also present a characterization (phase speed, amplitude and zonal wavenumber) of the previously detected circumpolar waves at 67° N and S at 890 nm and at about 50° N and −57° S at 258 nm that are a permanent phenomenon in Jupiter with some variability in its structure during the analyzed period. From the ensemble of data analyzed we propose the waves are Rossby waves whose dynamic behavior constrains plausible values for their meridional and vertical wavenumbers. This work demonstrates the long-term nature of Jupiter''s polar waves, providing a dynamical and vertical characterization which supports a detailed analysis of these phenomena in terms of a Rossby wave model. [Copyright &y& Elsevier]

Published

2008

15. The three-dimensional structure of Saturn's equatorial jet at cloud level

Author

Sánchez-Lavega, A., Hueso, R., and Pérez-Hoyos, S.

Subjects

*WIND speed measurement, *HEAT radiation & absorption, *MATHEMATICAL continuum, *MANURE gases

Abstract

Abstract: The three-dimensional structure of Saturn''s intense equatorial jet from latitudes 8° N to 20° S is revealed from detailed measurements of the motions and spectral reflectivity of clouds at visible wavelengths on high resolution images obtained by the Cassini Imaging Science Subsystem (ISS) in 2004 and early 2005. Cloud speeds at two altitude levels are measured in the near infrared filters CB2 and CB3 matching the continuum (effective wavelengths 750 and 939 nm) and in the MT2 and MT3 filters matching two methane absorption bands (effective wavelengths 727 and 889 nm). Radiative transfer models in selective filters covering an ample spectral range (250–950 nm) require the existence of two detached aerosol layers in the equator: an uppermost thin stratospheric haze extending between the pressure levels ∼20 and 40 mbar (tropopause level) and below it, a dense tropospheric haze-cloud layer extending between 50 mbar and the base of the ammonia cloud (between ∼1 and 1.4 bar). Individual cloud elements are detected and tracked in the tropospheric dense haze at 50 and 700 mbar (altitude levels separated by 142 km). Between latitudes 5° N and 12° S the winds increase their velocity with depth from 265 m s−1 at the 50 mbar pressure level to 365 m s−1 at 700 mbar. These values are below the high wind speeds of 475 m s−1 measured at these latitudes during the Voyager era in 1980–1981, indicating that the equatorial jet has suffered a significant intensity change between that period and 1996–2005 or that the tracers of the flow used in the Voyager images were rooted at deeper levels than those in Cassini images. [Copyright &y& Elsevier]

Published

2007

16. A strong vortex in Saturn's South Pole

Author

Sánchez-Lavega, A., Hueso, R., Pérez-Hoyos, S., and Rojas, J.F.

Subjects

*ATMOSPHERE, *SPACE vehicles, *POLAR vortex

Abstract

Abstract: Saturn''s southern pole was observed at high resolution by the Cassini Imaging Science Subsystem (ISS) during the spacecraft insertion orbit in July 2004. Cloud tracking of individual features on images taken at a wavelength of 938 nm reveal the existence of a strong polar vortex enclosed by a jet with maximum speed of relative to System III rotation frame, and peak at 87 °S planetographic latitude. Radiative transfer models of the reflected light, based on the Cassini images complemented by Hubble Space Telescope images from March 2004, indicate that the aerosol particles in the vortex are structured vertically in three detached layers. We find two hazes and one dense cloud distributed in altitude between (top of the dense cloud) and few mbar (top of the stratospheric haze), spanning a vertical altitude range of . The vortex area coincides with a thermal hot spot recently reported, indicating that winds decrease with altitude above polar clouds. [Copyright &y& Elsevier]

Published

2006

17. Dynamics of Jupiter’s equatorial region at cloud top level from Cassini and HST images

Author

García-Melendo, E., Arregi, J., Rojas, J.F., Hueso, R., Barrado-Izagirre, N., Gómez-Forrellad, J.M., Pérez-Hoyos, S., Sanz-Requena, J.F., and Sánchez-Lavega, A.

Subjects

*VERTICAL wind shear, *LATITUDE, *RADIATIVE transfer, *ASTROPHYSICAL jets, *ANTICYCLONES, *JUPITER (Planet)

Abstract

Abstract: We present a study of the equatorial region of Jupiter, between latitudes ∼15°S and ∼15°N, based on Cassini ISS images obtained during the Jupiter flyby at the end of 2000, and HST images acquired in May and July 2008. We examine the structure of the zonal wind profile and report the detection of significant longitudinal variations in the intensity of the 6°N eastward jet, up to 60ms−1 in Cassini and HST observations. These longitudinal variations are, in the HST case, associated with different cloud morphology. Photometric and radiative transfer analysis of the cloud features used as tracers in HST images show that at most there is only a small height difference, no larger than ∼0.5–1 scale heights, between the slow (∼100ms−1) and fast (∼150ms−1) moving features. This suggests that speed variability at 6°N is not dominated by vertical wind shears but instead we propose that Rossby wave activity is the responsible for the zonal variability. Removing this variability, we find that Jupiter’s equatorial jet is actually symmetric relative to equator with two peaks of ∼140–150ms−1 located at latitudes 6°N and 6°S and at a similar pressure level. We also study the local dynamics of particular equatorial features such as several dark projections associated with 5μm hot spots and a large, long-lived feature called the White Spot (WS) located at 6°S. Convergent flow at the dark projections appears to be a characteristic which depends on the particular morphology and has only been detected in some cases. The internal flow field in the White Spot indicates that it is a weakly rotating quasi-equatorial anticyclone relative to the ambient meridionally sheared flow. [Copyright &y& Elsevier]

Published

2011

18. Vertical shears in Saturn's eastward jets at cloud level

Author

García-Melendo, Enrique, Sánchez-Lavega, Agustín, Rojas, J.F., Pérez-Hoyos, S., and Hueso, R.

Subjects

*RADIATIVE transfer, *CLOUDS, *HAZE, *ATMOSPHERIC circulation, *ASTRONOMICAL models, *SATURN exploration, *SATURN (Planet)

Abstract

Abstract: We have measured the vertical shear of the zonal winds in the cloud-haze upper layer of Saturn using Cassini ISS images obtained in the filters MT2 (753 nm methane absorption band, sensitive to the upper haze) and CB2 (adjacent continuum, sensitive to the lower cloud). Our radiative transfer models indicate that at the eastward jet peaks these filters are sensing clouds at the respective ∼100 mbar and ∼350 mbar levels. We have found a systematic velocity difference between those filters of 15 to 20 m s−1 only in the eastward jets peaks (27° S, 42° S, 55° S and 70° S) which implies a vertical shear of ∼10–20 m s−1 H−1. Our overall results agree with those derived from the thermal-wind relationship using CIRS thermal data [Fletcher, L.N., and 13 colleagues, 2008. Science 319, 79–81] and with previous equatorial measurements [Sánchez-Lavega, A., Hueso, R., Pérez-Hoyos, S., 2007. Icarus 187, 510–519]. [Copyright &y& Elsevier]

Published

2009