Japan Geoscience Union Meeting 2014

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Poster

Symbol P (Space and Planetary Sciences) » P-CG Complex & General

[P-CG38_1PO1] Planetary atmosphere, ionosphere and magnetosphere

Thu. May 1, 2014 6:15 PM - 7:30 PM Poster (3F)

Convener:*Imamura Takeshi(Japan Aerospace Exploration Agency, Institute of Space and Astronautical Science), Kanako Seki(Solar-Terrestrial Environment Laboratory, Nagoya University), Yukihiro Takahashi Yukihiro(Department of Cosmosciences, Graduate School of Science, Hokkaido University), Yoshiyuki O. Takahashi(Center for Planetary Science), Keiichiro Fukazawa(Research Institute for Information Technology,Kyushu University), Hiromu Nakagawa(Planetary Atmosphere Physics Laboratory, Department of Geophysics, Graduate School of Science, Tohoku University)

6:15 PM - 7:30 PM

[PCG38-P02] Observation of CO2-ice cloud in the Martian mesosphere by using PFS onboard Mars Express

*Yuki SATO1, Yasumasa KASABA1, Giuranna MARCO2, Shohei AOKI1, Hiromu NAKAGAWA1, Takeshi KURODA3 (1.Planetary Atmosphere , TOHOKU University, 2.IAPS,INAF,Italy, 3.Planetary Plasma and Atmospheric Research Center , TOHOKU University)

Keywords:Mars, CO2-ice cloud

Almost all of constituent of martian atmosphere is CO2 (95%). It condenses at very high altitude (60~100km) and become cloud. CO2-ice cloud have been observed by many instrument , but it was difficult to clearly judge whether observed cloud is made of CO2 or not. However OMEGA, visible and near-infrared imaging spectrometer onboard Mars Express, have provided the first spectroscopic identification of a cloud as being composed of CO2 (Montmessin et al, 2007) CO2-ice cloud has characteristic spectral feature emission peak at 4.26μm. Recent study reported that CO2-ice cloud distributes around equator in spring equinox to early summer and mid latitude in local autumn. (Maattanen et al,2010 , Montmessin et al,2007 2006, Clancy et al 2007) However, it is not clear about cloud feature (particle size or opacity ). We try to observe CO2-ice cloud using high spectral resolution instrument PFS, infrared fourier spectrometer onboard Mars Express. Strong point of PFS is that spectral resolution is ten times greater than that of OMEGA and We can see spectral feature of CO2-ice cloud (spike at 4.26μm) more clearly. Another point is that PFS and OMEGA observe almost the same point , so two instruments can observe CO2-ice cloud at the same time. For the first step, we check the data where OMEGA observed CO2-ice cloud (10 orbits) and found CO2-ice cloud like feature all of the 10 orbits. However emission peak appears at shorter wavelength ( at 4.25 μm) . In order to judge whether this signal is real or not, we compared PFS spectra and OMEGA spectra observed at the same point. When PFS observe signal at 4.25μm , OMEGA also show strong signal at 4.26μm ,so we can say PFS signal is real. In some orbit, PFS observed different signal from that of OMEGA. It is double spike feature at 4.25μm and 4.28μm which OMEGA can not resolve. It is possible that double peak feature shows different cloud feature, for example, particle size.Now we are trying radiative transfer model and discuss how cloud spectral feature changes when we changes cloud parameter (size distribution, altitude, cloud opacity ).