Secondary-ion and electron production from surfaces bombarded by large polyatomic ions
Heavy molecular ions with energies in the range 10–20 keV and masses from 276 u to 132 000 u, produced by matrix‐assisted laser desorption, were used as primary projectiles to produce secondary‐ion spectra from a variety of surfaces ina tandem time‐of‐fight mass spectrometer. In the negative mode th...
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Veröffentlicht in: | Rapid communications in mass spectrometry 1992-02, Vol.6 (2), p.147-157 |
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Sprache: | eng |
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Zusammenfassung: | Heavy molecular ions with energies in the range 10–20 keV and masses from 276 u to 132 000 u, produced by matrix‐assisted laser desorption, were used as primary projectiles to produce secondary‐ion spectra from a variety of surfaces ina tandem time‐of‐fight mass spectrometer. In the negative mode the ratio of electron emission to secondary‐ion emission was found to decrease rapidly with increasing projectile mass. Ion emission was found to dominate for primary ions larger than ∼ 10 000 u. Positive or negative molecular ions and cations were observed from several organic targets of masses up to 1140 u (gramicidin S) for incident projectiles up to mass 132 000 u, i. e., for projectile speeds down to ∼7000 m/s. Other ions characteristic of the target were also observed for these projectiles. Thus, large polyatomic ions can cause secondary‐ion desorption even at very low velocity. The background ions of both polarities are similar to those found in keV particle bombardment by monatomic projectiles. The same ions are observed for all the projectiles; most can be identified with hydrocarbon background. The relative intensities of the background positive ions are largely independent of projectile, and for both polarities the ratio of the ions characterizing the target to those forming the background is approximately constant for all the projectiles. These results strongly suggest that the background ions come from the usual layer of organic impurities attached to the target surface. No direct evidence for surface‐induced dissociation was observed in this mass and energy range. |
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ISSN: | 0951-4198 1097-0231 |
DOI: | 10.1002/rcm.1290060215 |