Studies of Singly and Multiply Charged Secondary Ion Emission And The Effects Of Oxygen On Ionization And Sputter Erosion

• Other Authors: Sobers Jr., Richard Carlisle (Author)
• Format: Doctoral Thesis
• Language: English
• Published: 2012
• Subjects: Chemistry; Analytical chemistry; Decay Length; Diatomic Dications; Ion Yield; Secondary Ion Mass Spectrometry; SIMS; Sputter Yield
• Online Access: http://hdl.handle.net/2286/R.I.15214

abstract: Mass spectrometric analysis requires that atoms from the sample be ionized in the gas phase. Secondary ion mass spectrometry achieves this by sputtering samples with an energetic primary ion beam. Several investigations of the sputtering and ionization process have been conducted. Oxygen is commonly used in secondary ion mass spectrometry (SIMS) to increase ion yields, but also can complicate the interpretation of SIMS analyses. An 18O implant in silicon has been used to quantify the oxygen concentration at the surface of sputtered silicon in order to study the dependence on oxygen of several sputtering and depth profile phenomena. The ion yield dependence of trace elements in silicon on the surface oxygen concentration is a function of the ionization potential of the element. The ion yield is high and unaffected by oxygen for elements with low ionization potential and ranges over several orders of magnitude for elements with high ionization potential. Depth resolution in sputter profiles has been shown to be degraded by the presence of oxygen, the mechanism of this effect has been investigated using an 18O implant to quantify oxygen levels and it is shown that the process does not appear to be a consequence of surface oxide formation. Molecular ions are a source of mass interference in SIMS analysis, and multiply charged atomic ion signals might be interference-free due to the possible instability of multiply-charged molecular ions. Sputtered SiH2+, AlH2+, BeH2+, Mo22+ and Mg22+ ions have been observed and appear surprisingly stable. The formation mechanism of some of these species has been explored. === Dissertation/Thesis === Ph.D. Chemistry 2012