TY - JOUR
T1 - Retrieval of jovian cloud structure from the Cassini ISS limb-darkening data. I. Continuum scattering phase functions for cloud and haze in the South Tropical Zone.
AU - Sato, T. M.
AU - Satoh, T.
AU - Kasaba, Y.
N1 - Funding Information:
In this study, we made use of the Cassini ISS images available at the NASA Planetary Data System (PDS). We are grateful to the Cassini ISS team for providing valuable data. We wish to thank Dr. R. West and Dr. B. Knowles for helpful discussion about data calibration. T.M. Sato is supported by a Grant-in-Aid for the Japan Society for the Promotion of Science (JSPS) Fellows. This work is supported by a Grant-in-Aid for Scientific Research (22340142) and by the Tohoku University Global COE program titled “Global Education and Research Center for Earth and Planetary Dynamics.”
PY - 2013/1
Y1 - 2013/1
N2 - We have deduced the scattering properties of aerosols in the jovian upper troposphere by analyzing imaging data obtained at a wide variety of solar phase angles (4-140°) by the Cassini Imaging Science Subsystem (ISS) Narrow Angle Camera (NAC) during its flyby of Jupiter. The limb-darkening curves along the South Tropical Zone (STrZ) are extracted from CB2 images (effective wavelength: 750nm) to constrain the single scattering phase functions of aerosols. The best-fit Mie scattering phase function for cloud is obtained with the real part of the refractive index n r,cloud=1.85 and the effective radius r eff,cloud=0.3μm. The best-fit combination of n r,cloud and r eff,cloud would strongly suggest the idea that the abundant small particle population in the upper troposphere is not composed of pure NH 3 ice. Although the optical properties of the stratospheric haze are not well constrained compared with those of cloud, the haze is found to be optically thin (<0.06) and to be strongly forward scattering (effective radius r eff,haze=0.5μm).We compare our results with the scattering phase function at red wavelength (640. nm) for the STrZ derived by Tomasko et al. (Tomasko, M.G., West, R.A., Castillo, N.D. [1978]. Icarus 33, 558-592), which was deduced from analysis of the Pioneer 10 Imaging Photopolarimeter (IPP) data (12-150° for solar phase angles). Our new Mie scattering phase function can reproduce the Pioneer 10 observations well. In contrast, their scattering phase function described by the double Henyey-Greenstein function does not reproduce the Cassini ISS observations. This is attributed to the fact that their scattering phase function is underconstrained, primarily due to a considerable gap in observations for an intermediate solar phase angle range (34-109°).Our new Mie scattering phase function has advantages over that of Tomasko et al. (Tomasko, M.G., West, R.A., Castillo, N.D. [1978]. Icarus 33, 558-592).(1)Since the Cassini ISS data do not have a large gap in solar phase angle, the new Mie scattering phase function is better constrained.(2)The Mie scattering phase function can be applied easily to different wavelengths.With such characteristics, we now have a reliable baseline scattering phase function that can be used to interpret the ever-changing appearance of jovian clouds as changes of the vertical cloud structure and/or distribution of chromophores in the atmosphere.
AB - We have deduced the scattering properties of aerosols in the jovian upper troposphere by analyzing imaging data obtained at a wide variety of solar phase angles (4-140°) by the Cassini Imaging Science Subsystem (ISS) Narrow Angle Camera (NAC) during its flyby of Jupiter. The limb-darkening curves along the South Tropical Zone (STrZ) are extracted from CB2 images (effective wavelength: 750nm) to constrain the single scattering phase functions of aerosols. The best-fit Mie scattering phase function for cloud is obtained with the real part of the refractive index n r,cloud=1.85 and the effective radius r eff,cloud=0.3μm. The best-fit combination of n r,cloud and r eff,cloud would strongly suggest the idea that the abundant small particle population in the upper troposphere is not composed of pure NH 3 ice. Although the optical properties of the stratospheric haze are not well constrained compared with those of cloud, the haze is found to be optically thin (<0.06) and to be strongly forward scattering (effective radius r eff,haze=0.5μm).We compare our results with the scattering phase function at red wavelength (640. nm) for the STrZ derived by Tomasko et al. (Tomasko, M.G., West, R.A., Castillo, N.D. [1978]. Icarus 33, 558-592), which was deduced from analysis of the Pioneer 10 Imaging Photopolarimeter (IPP) data (12-150° for solar phase angles). Our new Mie scattering phase function can reproduce the Pioneer 10 observations well. In contrast, their scattering phase function described by the double Henyey-Greenstein function does not reproduce the Cassini ISS observations. This is attributed to the fact that their scattering phase function is underconstrained, primarily due to a considerable gap in observations for an intermediate solar phase angle range (34-109°).Our new Mie scattering phase function has advantages over that of Tomasko et al. (Tomasko, M.G., West, R.A., Castillo, N.D. [1978]. Icarus 33, 558-592).(1)Since the Cassini ISS data do not have a large gap in solar phase angle, the new Mie scattering phase function is better constrained.(2)The Mie scattering phase function can be applied easily to different wavelengths.With such characteristics, we now have a reliable baseline scattering phase function that can be used to interpret the ever-changing appearance of jovian clouds as changes of the vertical cloud structure and/or distribution of chromophores in the atmosphere.
KW - Atmospheres, Structure
KW - Jupiter, Atmosphere
KW - Radiative transfer
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U2 - 10.1016/j.icarus.2012.09.035
DO - 10.1016/j.icarus.2012.09.035
M3 - Article
AN - SCOPUS:84870231319
SN - 0019-1035
VL - 222
SP - 100
EP - 121
JO - Icarus
JF - Icarus
IS - 1
ER -