Evaluation of the Possibilities of the STV CCD Detector for the Observations of Planets

The results of planetary observations performed with a new CCD detector are presented. The available firmware for collecting a great number of electronic images and the high quantum efficiency of the employed CCD make it possible to observe objects the visibility of which is limited by the short duration of astronomical phenomena. Among such tasks are, for instance, the taking of a large number of images of Mercury by the short exposure method. With a high quantum efficiency of the light detector, short exposure makes it possible to appreciably reduce the blurring of astronomical images caused by the atmospheric instability. This study was performed at the Abastumani Astrophysical Observatory of the Republic of Georgia early in November 2001.     

A Spectropolarimetric Maturity Index of Lunar Soil

The lunar soil maturity is the most important parameter of the Moon's surface material. The degree of regolith processing should be taken into account in remote determinations of the chemical and mineralogical surface compositions. However, the possibilities for directly determining the lunar regolith maturity are limited to laboratory studies of the fine fraction and microparticles of samples returned to Earth. In these conditions, the urgency of developing methods for remotely determining the lunar soil maturity increases sharply. The suggested method of using spectropolarimetric data to quantitatively estimate the maturity of the surface material has an advantage that the derived maturity index is determined only by structural parameters of the reflecting layer and is completely free from the effects of chemical and mineralogical surface rock compositions. The reference catalog of spectropolarimetric indices contains values for 92 objects on the Moon's visible hemisphere and includes a wide range of structures with various degrees of maturity of the surface material. We obtained correlations with other maturity indices determined by laboratory and remote sensing techniques and the time scale that represents the correspondence between the spectropolarimetric maturity index and the soil exposure age.     

Modern slope processes on the moon

Slope movements of material in lunar craters are investigated based on remote spectral studies carried out on board the Clementine spacecraft, and data obtained during the large-scale survey on board the LRO (Lunar Reconnaissance Orbit) spacecraft. The morphological analysis of crater forms based on large-scale images and spectral and spectropolarized assessments of the exposition age (or maturity) of the slope material has led to the conclusion that the formation process of observed outcrops probably is a modern feature. The lower age limit of these structures is estimated at 40–80 years. Thus, slope movements of surface materials can continue at the present time, regardless of the age of the crater studied. Slope movements of crushed granular material lead to fresh outcrops of subsurface layers of marine or continental landscapes and, therefore, extend our capabilities to research the deep material of the Moon. To analyze this phenomenon, craters of 16 and 30 km have been selected. The length of fresh outcrops, while depending strongly on the dimensions of the craters, can be up to several kilometers. In connection with this, the prospect appears of remote analysis of rocks that came to the surface from depths of at least several hundred meters. In this case, there are openings for the contact analysis of subsurface material without the use of labor-intensive operations associated with the delivery of equipment for deep drilling to the lunar surface.