Kieffer, H.H., Titus, T.N., Mullins, K.F., Becker, K., Johnson, J., Christensen, P.
The early part of the Mars Global Surveyor mission provided good TES coverage of the Mars south polar region.
These data allow mapping of the polar cap recession, surface and atmospheric temperatures, and albedo features found within the seasonal cap itself (Kieffer et al, 1998, Titus et al, 1998). During the period observed, the seasonal south polar cap retreated continuously and asymmetrically around the geographic pole, much the way Viking observed in 1976-1977 (Kieffer et al., 1977). One of the most dominant albedo features on the seasonal cap is a region that appears almost as dark as bare ground, but yet remains cold. (See Figure 1.) We refer to this region, generally located between latitudes 85° S and 75° S and longitudes 150° W and 310° W, as the Cryptic region. A re-examination of the IRTM data revealed that the Cryptic region was not unique to the TES era, but also was quite appearant during the Viking era. (See Figure 2.) Interesting enough, Antoniadi (Blunck, 1977) observed dark regions forming on the season cap that loosely correlates to the Cryptic region: Depressio Magna (1909) and Depressio Parva (1929). These depressios were located at 270° W, 78° S and 166° W, 76° S, respectively. Analysis of both the TES and IRTM data indicate that the Cryptic region is unique in its thermophysical properties relative to the rest of the cap. The region is a repeatable event that occupies the same general area from year to year. It is darker and slightly warmer than the rest of the south polar cap. Even though the Cryptic region is slightly warmer, it must still be CO2 buffered since it remains “ cold ” for several days. Spectral analysis of the TES longward of the 15 micron atmospheric band shows that the Cryptic region shows less spectral than the rest of the polar cap. This suggests that the region may be composed of “ ice ”, as opposed to snow or frost (Hansen, 1998). Further spectral analysis is on going.
Figure 1: These two images are maps of TES data, showing Lambert albedo and TES “ T20 ” of the south polar cap. (The TES “ T20 ” is a synthetic band created by convolving the response function of the IRTM 20µm filter with the TES spectra.) The images are composites from the first rolls of orbit 43 (Ls=219.2°, Nov 17,1997) and orbit 45 (Ls=220.8°, Nov 20, 1997). The Cryptic region is the blue area in the albedo image, curving along the 80° S latitude line. The region shows up in the thermal image as only slightly warmer than the rest of the polar cap, but still too cold to be bare ground.
Figure 2: These two images are from the Viking 2 IRTM, showing Lambert albedo and T20 of the seasonal south polar cap. The data is from Ls221.2° (March 14, 1977). The albedo and thermal images show many of the same characteristics as the TES images (Figure 1).
References: Blunck, J, 1977, "Mars and its Satellites: A detailed Commentary on the Nomenclature" Hansen,G., 1998, Control of the radiative behavior of the Martian polar caps by surface CO2 ice: Evidence from Mars Global Surveyor measurements, J. Geophys. Res. Vol. 104 , No. E7 , p. 16,471. Kieffer,H., Titus, T., Mullins, K.,1998, Early TES Observations of the South Polar Region, In Lunar and Planetary Science XXIX, Abstract 1481, Lunar and Planetary Institute, Houston (CD-ROM). Kieffer, H.H., Martin, T.Z., Peterfreund, R., Jakosky, B.M., Miner, E.D., Palluconi, F.D., 1977, JGR, 82, 4249-4291. Titus, T., Kieffer, H., Mullins, K., 1998, TES Observations of the South Pole, BAAS, vol. 30, no. 3, 1049-1050.
Below are other science projects associated with this project.
SP Recession
South Pole
All About Ice
Consortium Meetings
Mars Ice
Mars Ice Consortium
- Overview
Kieffer, H.H., Titus, T.N., Mullins, K.F., Becker, K., Johnson, J., Christensen, P.
The early part of the Mars Global Surveyor mission provided good TES coverage of the Mars south polar region.
These data allow mapping of the polar cap recession, surface and atmospheric temperatures, and albedo features found within the seasonal cap itself (Kieffer et al, 1998, Titus et al, 1998). During the period observed, the seasonal south polar cap retreated continuously and asymmetrically around the geographic pole, much the way Viking observed in 1976-1977 (Kieffer et al., 1977). One of the most dominant albedo features on the seasonal cap is a region that appears almost as dark as bare ground, but yet remains cold. (See Figure 1.) We refer to this region, generally located between latitudes 85° S and 75° S and longitudes 150° W and 310° W, as the Cryptic region. A re-examination of the IRTM data revealed that the Cryptic region was not unique to the TES era, but also was quite appearant during the Viking era. (See Figure 2.) Interesting enough, Antoniadi (Blunck, 1977) observed dark regions forming on the season cap that loosely correlates to the Cryptic region: Depressio Magna (1909) and Depressio Parva (1929). These depressios were located at 270° W, 78° S and 166° W, 76° S, respectively. Analysis of both the TES and IRTM data indicate that the Cryptic region is unique in its thermophysical properties relative to the rest of the cap. The region is a repeatable event that occupies the same general area from year to year. It is darker and slightly warmer than the rest of the south polar cap. Even though the Cryptic region is slightly warmer, it must still be CO2 buffered since it remains “ cold ” for several days. Spectral analysis of the TES longward of the 15 micron atmospheric band shows that the Cryptic region shows less spectral than the rest of the polar cap. This suggests that the region may be composed of “ ice ”, as opposed to snow or frost (Hansen, 1998). Further spectral analysis is on going.
Sources/Usage: Public Domain.
Sources/Usage: Public Domain.Figure 1: These two images are maps of TES data, showing Lambert albedo and TES “ T20 ” of the south polar cap. (The TES “ T20 ” is a synthetic band created by convolving the response function of the IRTM 20µm filter with the TES spectra.) The images are composites from the first rolls of orbit 43 (Ls=219.2°, Nov 17,1997) and orbit 45 (Ls=220.8°, Nov 20, 1997). The Cryptic region is the blue area in the albedo image, curving along the 80° S latitude line. The region shows up in the thermal image as only slightly warmer than the rest of the polar cap, but still too cold to be bare ground.
Sources/Usage: Public Domain.
Sources/Usage: Public Domain.Figure 2: These two images are from the Viking 2 IRTM, showing Lambert albedo and T20 of the seasonal south polar cap. The data is from Ls221.2° (March 14, 1977). The albedo and thermal images show many of the same characteristics as the TES images (Figure 1).
References: Blunck, J, 1977, "Mars and its Satellites: A detailed Commentary on the Nomenclature" Hansen,G., 1998, Control of the radiative behavior of the Martian polar caps by surface CO2 ice: Evidence from Mars Global Surveyor measurements, J. Geophys. Res. Vol. 104 , No. E7 , p. 16,471. Kieffer,H., Titus, T., Mullins, K.,1998, Early TES Observations of the South Polar Region, In Lunar and Planetary Science XXIX, Abstract 1481, Lunar and Planetary Institute, Houston (CD-ROM). Kieffer, H.H., Martin, T.Z., Peterfreund, R., Jakosky, B.M., Miner, E.D., Palluconi, F.D., 1977, JGR, 82, 4249-4291. Titus, T., Kieffer, H., Mullins, K., 1998, TES Observations of the South Pole, BAAS, vol. 30, no. 3, 1049-1050.
- Science
Below are other science projects associated with this project.
SP Recession
TES Observations of the South PoleT.N. Titus (Oak Ridge Associated Universities), H.H. Kieffer, K.F. Mullins (U.S. Geological Survey)he recession of the south polar cap has been observed telescopically and from spacecraft in both the visible and thermal regions. Although a simple cap-edge versus time plot has commonly been used, without regard as to the longitude of measurement, Mariner 9, Viking...South Pole
Jets on MarsNature, August 2006. CO2 Jets on Mars: Scientists have now found a better explanation for the dark spots and fans found on the south polar region of Mars. These spots, which can cover tens of square kilometers, are visible in the cryptic region. Originally, it was suggested that the spots were soil, exposed after early defrosting of the polar ice. However, an intensive new study with...All About Ice
Why Study Ice on Mars?On Earth, there’s a plethora of variables driving environmental change, from natural processes to the activities of humans. While Mars is most similar to Earth of all the known extraterrestrial worlds, its climate is still extremely different from our watery abode. The recent discovery of ice on the red planet’s surface has given us a new climate driver to study...Consortium Meetings
Consortium MeetingsConsortium hosted meetings will be listed below. If you would like to attend any of these meetings, please be sure to register. Should your plans change after you register, you may simply reregister with your changes detailed appropriately.Please follow these links to view summaries of past consortium hosted workshops.Mars Ice
The Mars-Ice project is a joint project between the USGS Astrogeology Research Program (Flagstaff, AZ) and the Arizona State University Mars Space Flight Facilty (Tempe, AZ) to bring together a single resource for the exploration of martian ices. Much of this research is done at the USGS Flagstaff Science Center.Mars Ice Consortium
The Mars Ice Consortium is a joint project between the USGS Astrogeology Research Program (Flagstaff, AZ) and the Arizona State University Mars Space Flight Facilty (Tempe, AZ) to bring together a single resource for the exploration of martian ices. Much of this research is done at the USGS Flagstaff Science Center.