| Molecular hydrogen is by far the most abundant molecule in space. H;This thesis reports on laboratory measurements of molecular hydrogen formation and recombination on surfaces of astrophysical interest. It also describes how atomic/molecular beam and surface science techniques can be used to study physical processes leading to the formation of hydrogen molecules at surfaces under conditions relevant to those encountered in the interstellar medium.;Flash desorption experiments have been conducted to yield desorption energies, order of desorption kinetics and recombination efficiency (defined as the sticking probability S times the probability of recombination upon H-H encounter, ;The recombination rates are obtained as functions of surface temperature and exposure time to H and D atom beams. Our measurements give lower values for the recombination efficiency than model-based estimates. We propose that our results can be reconciled with average estimates of the recombination rate from astronomical observations, if the actual surface of an average grain is rougher, and its area bigger, than the one considered in models. On the basis of our experimental evidence, we recognize that there are two main regimes of H coverage that are of astrophysical importance; for each of them we provide an expression giving the production rate of molecular hydrogen in interstellar clouds. |
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