Add to ORKGThe yttrium and zirconium abundances are determined in a sample of 20 metal-poor stars on the basis of high resolution, high SNR spectra. Significant differences between the behaviors of these two neighboring elements are found, zirconium being less deficient than yttrium in Population II stars. Moreover, there is a genuine cosmic scatter in the abundances of these two elements relative to iron, of the order of 20 percent. The scatter is lower when these elements are compared to titanium, which might indicate that a significant fraction of the lighter neutron-capture elements are produced in massive stars
We suggest a method of determining the relative contributions from individual neutron capture proces...
To better characterize the abundance patterns produced by the r-process, we have derived new abundan...
We have derived new detailed abundances of Mg, Ca, and the Fe-group elements Sc through Zn ( Z = 21−...
Elemental abundance measurements have been obtained for a sample of 18 very metal-poor stars using s...
We use a large set of high S/N, high resolution spectra of 19 stars with -2.8 <[Fe/H]< 0 to study th...
We apply our model for calculating the heavy element abundance in metal-poor stars to recent data of...
International audienceThe abundance patterns of the neutron-capture elements in metal-poor stars pro...
International audienceThis paper reports on the abundance determination of neutron-capture elements ...
This work is devoted to the study of abundances in mildly metal-poor stars. We have selected 21 unev...
We derived Sr, Y, Zr, and Ce abundances for a sample of 74 cool dwarfs and subgiants with iron abund...
New abundances for neutron-capture elements in a large sample of metal-poor giants from the Bond sur...
Due to their ubiquity and very long main-sequence lifetimes, abundance determinations in M dwarfs pr...
We obtained high-resolution, high signal-to-noise ratio (S/N) spectroscopy for the very metal poor s...
Chemical compositions of stars provide us with unique information about their nucleosynthesis proces...
We present new abundances of the lighter n-capture elements, Yttrium (Z=30) and Zirconium (Z=40) in ...
We suggest a method of determining the relative contributions from individual neutron capture proces...
To better characterize the abundance patterns produced by the r-process, we have derived new abundan...
We have derived new detailed abundances of Mg, Ca, and the Fe-group elements Sc through Zn ( Z = 21−...
Elemental abundance measurements have been obtained for a sample of 18 very metal-poor stars using s...
We use a large set of high S/N, high resolution spectra of 19 stars with -2.8 <[Fe/H]< 0 to study th...
We apply our model for calculating the heavy element abundance in metal-poor stars to recent data of...
International audienceThe abundance patterns of the neutron-capture elements in metal-poor stars pro...
International audienceThis paper reports on the abundance determination of neutron-capture elements ...
This work is devoted to the study of abundances in mildly metal-poor stars. We have selected 21 unev...
We derived Sr, Y, Zr, and Ce abundances for a sample of 74 cool dwarfs and subgiants with iron abund...
New abundances for neutron-capture elements in a large sample of metal-poor giants from the Bond sur...
Due to their ubiquity and very long main-sequence lifetimes, abundance determinations in M dwarfs pr...
We obtained high-resolution, high signal-to-noise ratio (S/N) spectroscopy for the very metal poor s...
Chemical compositions of stars provide us with unique information about their nucleosynthesis proces...
We present new abundances of the lighter n-capture elements, Yttrium (Z=30) and Zirconium (Z=40) in ...
We suggest a method of determining the relative contributions from individual neutron capture proces...
To better characterize the abundance patterns produced by the r-process, we have derived new abundan...
We have derived new detailed abundances of Mg, Ca, and the Fe-group elements Sc through Zn ( Z = 21−...