Dopant ionization and efficiency of ion and electron ejection from helium nanodroplets
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Photoionization spectroscopy and mass spectrometry of doped helium (He) nanodroplets rely on the ability to efficiently detect ions and/or electrons. Using a commercial quadrupole mass spectrometer and a photoelectron-photoion coincidence (PEPICO) spectrometer, we systematically measure yields of ions and electrons created in pure and doped He nanodroplets in a wide size range and in two ionization regimes -- direct ionization and secondary ionization after resonant photoexcitation of the droplets. For two different types of dopants (oxygen molecules, O$_2$, and lithium atoms, Li), we infer the optimal droplet size to maximize the yield of ejected ions. When dopants are ionized by charge-transfer to photoionized He nanodroplets, the highest yield of O$_2$ and Li ions is detected for a mean size of $\sim5\times10^4$ He atoms per nanodroplet. When dopants are Penning ionized via photoexcitation of the He droplets, the highest yield of O$_2$ and Li ions is detected for $\sim10^3$ and $\sim10^5$ He atoms per droplet, respectively. At optimum droplet sizes, the detection efficiency of dopant ions in proportion to the number of primary photoabsorption events is up to 20\,\% for charge-transfer ionization of O$_2$ and 2\,\% for Li, whereas for Penning ionization it is 1\,\% for O$_2$ and 4\,\% for Li. Our results are instrumental in determining optimal conditions for mass spectrometric studies and photoionization spectroscopy of molecules and complexes isolated in He nanodroplets.
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