We report on the first results of experiments to measure the recombination rate of hydrogen on surfaces of astrophysical interest. Our measurements give lower values for the recombination efficiency (sticking probability S x probability of recombination upon H-H encounter $\gamma$) than model-based estimates. We propose that our results can be reconciled with average estimates of the recombination rate (1/2 n(H) n(g) v(H)A S $\gamma$) from astronomical observations, if the actual surface of an average grain is rougher, and its area bigger, than the one considered in models
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
A hydrogen molecule that is formed on an interstellar grain might retain some of the 4.48 eV of ener...
We report on the first results of experiments to measure the recombination rate of hydrogen on surfa...
Molecular hydrogen is by far the most abundant molecule in space. H$\sb2$ formation in the interstel...
Recent experimental results on the formation of molecular hydrogen on astrophysically relevant surfa...
Recent experimental results about the formation of molecular hydrogen on astrophysically relevant su...
Recent experimental results about the formation of molecular hydrogen on astrophysically relevant su...
Molecular hydrogen has an important role in the early stages of star formation as well as in the pro...
We report on laboratory measurements of molecular hydrogen formation and recombination on an olivine...
Aims.In interstellar clouds, molecular hydrogens are formed from atomic hydrogen on grain surfaces. ...
In the last four years we have been working to investigate the formation of molecular hydrogen on su...
We have developed a model for molecular hydrogen formation under astrophysically relevant conditions...
Our laboratory research program is about the formation of molecules on dust grains analogues in cond...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
A hydrogen molecule that is formed on an interstellar grain might retain some of the 4.48 eV of ener...
We report on the first results of experiments to measure the recombination rate of hydrogen on surfa...
Molecular hydrogen is by far the most abundant molecule in space. H$\sb2$ formation in the interstel...
Recent experimental results on the formation of molecular hydrogen on astrophysically relevant surfa...
Recent experimental results about the formation of molecular hydrogen on astrophysically relevant su...
Recent experimental results about the formation of molecular hydrogen on astrophysically relevant su...
Molecular hydrogen has an important role in the early stages of star formation as well as in the pro...
We report on laboratory measurements of molecular hydrogen formation and recombination on an olivine...
Aims.In interstellar clouds, molecular hydrogens are formed from atomic hydrogen on grain surfaces. ...
In the last four years we have been working to investigate the formation of molecular hydrogen on su...
We have developed a model for molecular hydrogen formation under astrophysically relevant conditions...
Our laboratory research program is about the formation of molecules on dust grains analogues in cond...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
The most abundant interstellar molecule, H-2, is generally thought to form by recombination of H ato...
A hydrogen molecule that is formed on an interstellar grain might retain some of the 4.48 eV of ener...