Abstract. Volatiles, and water in particular, have been thought to be unstable on the lunar surface because of the rapid removal of constituents of the lunar atmosphere by solar radiation, solar wind, and gravitational escape. The limiting factor in removal of a volatile from the moon, however, is actually the evaporation rate of the solid phase, which will be collected at the coldest points on the lunar surface. We present a detailed theory of the behavior of volatiles on the lunar surface based on solid-vapor kinetic relationships, and show that water is far more stable there than the noble gases or other possible constituents of the lunar atmosphere. Numerical calculations indicate the amount of water lost from the moon since the present surface conditions were initiated is only a few grams per square centimeter of the lunar surface. The amount of ice eventually detected in lunar 'cold traps' thus will provide a sensitive indication of the degree of chemical differentiation of the moon.
It is generally presumed that gases of low molecular weight escape very rapidly from the moon. As a consequence, it has been assumed that volatile substances, such as water, which possess short relaxation times for escape, do not exist there. Urey [1952] We are using 120øK, however, because it is a reasonable upper limit. Extrapolation of observed vapor pressure data for ice indicates that at
Our goal in this study was to define the mechanisms by which fetuin-A mediates the adhesion of tumor cells. The data show that in the absence of fetuin-A, detached tumor cells secrete exosomes that contain most of the known exosomal associated proteins but lack the capacity to mediate cellular adhesion. In the presence of fetuin-A, the cells secrete exosomes, which contain, in addition to the other exosomal proteins, fetuin-A, plasminogen and histones. These exosomes mediate adhesion and cell spreading. Plasminogen is a participant in this novel adhesion mechanism. The data suggest that these exosomes play a role in tumor progression.
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