Abstract
Emission spectra from multiply-charged Sn5+–Sn10+ ions are recorded from an electron beam ion trap (EBIT) and from laser-produced plasma (LPP) in the extreme ultraviolet range relevant for nanolithographic applications. Features in the wavelength regime between 12.6 and 20.8 nm are studied. Using the Cowan code, emission line features of the charge-state-resolved Sn ion spectra obtained from the EBIT are identified. Emission features from tin LPP either from a liquid micro-droplet or planar solid target are subsequently identified and assigned to specific charge states using the EBIT data. For the planar solid tin target, the 4d–5p transitions of Sn8+–Sn10+ ions are shown to dominate the long-wavelength part of the measured spectrum and transitions of type 4d–4f + 4p–4d are visible in absorption. For the droplet target case, a clear increase in the charge state distribution with increasing laser intensity is observed. This qualitatively demonstrates the potential of using long-wavelength out-of-band emission features to probe the charge states contributing to the strong unresolved transition array at 13.5 nm relevant for nanolithography.
Highlights
Charged Sn ions in laser-driven transient and dense plasmas are the emitters of extreme ultraviolet (EUV) light near 13.5 nm that is used in nanolithographic applications [1,2,3,4]
Emission spectra from multiply-charged Sn5+–Sn10+ ions are recorded from an electron beam ion trap (EBIT) and from laser-produced plasma (LPP) in the extreme ultraviolet range relevant for nanolithographic applications
Emission spectra from multiply-charged Sn5+–Sn10+ ions are recorded from an EBIT and from LPP in the EUV range
Summary
Charged Sn ions in laser-driven transient and dense plasmas are the emitters of extreme ultraviolet (EUV) light near 13.5 nm that is used in nanolithographic applications [1,2,3,4]. Spectral features in the emission from Sn LPP, generated from liquid droplets as well as from planar solid tin targets over a wide range of laser intensities (and plasma temperatures), are identified using the EBIT spectra. These investigations extend the set of diagnostic tools for monitoring EUV-producing tin LPP in an industrial setting
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