KANICKÝ, Viktor, Vítězslav OTRUBA and Jean-Michel MERMET. Depth profiling of tin-coated glass by laser ablation inductively coupled plasma atomic emission spectrometry with acoustic signal measurement. Fresenius Journal of Analytical Chemistry. Berlin: Springer-Verlag, 2000, vol. 366, No 3, p. 228-233. ISSN 0937-0633.
Other formats:   BibTeX LaTeX RIS
Basic information
Original name Depth profiling of tin-coated glass by laser ablation inductively coupled plasma atomic emission spectrometry with acoustic signal measurement
Authors KANICKÝ, Viktor (203 Czech Republic, guarantor), Vítězslav OTRUBA (203 Czech Republic) and Jean-Michel MERMET (250 France).
Edition Fresenius Journal of Analytical Chemistry, Berlin, Springer-Verlag, 2000, 0937-0633.
Other information
Original language English
Type of outcome Article in a journal
Field of Study 10406 Analytical chemistry
Country of publisher Germany
Confidentiality degree is not subject to a state or trade secret
Impact factor Impact factor: 1.418
RIV identification code RIV/00216224:14310/00:00002272
Organization unit Faculty of Science
Keywords in English Laser ablation; Inductively coupled plasma; Atomic emission spectrometry; Tin coating; Glass
Tags atomic emission spectrometry, glass, inductively coupled plasma, laser ablation, Tin coating
Tags International impact, Reviewed
Changed by Changed by: prof. RNDr. Viktor Kanický, DrSc., učo 408. Changed: 29/6/2007 10:25.
Abstract
A pulsed, frequency-quadrupled Nd:YAG laser (266 nm, 10 Hz) coupled to an inductively coupled plasma atomic emission spectrometer (ICP-AES) was employed for depth profiling by ablation of a pyrolytically deposited Sn layer (300 nm) on float glass. The procedure consisted of performing individual ablation cycles (layer-by-layer). A raster with stroke distance of either 50 mu m or 200 mu m (the raster density) was used as an ablation pattern. The ablation was stopped after each cycle and the peal; area of the resulting transient optical signal of the ICP discharge was plotted against the cycle number. The ablation rate of 90 to 20 nm per cycle at a low-energy pulse (6 mJ to 1 mJ) was determined by profilometry. A beam masking was employed to attenuate the laser shot energy and to eliminate the peripheral irregularity of the beam profile. Almost uniform removal of the square area (1 mm x 1 mm) of the coating by ablation was achieved by combining the fitted raster density, beam masking, focusing and beam energy. Different ablation processes were distinguished in cases of the tin coating and the uncoated glass surface. While the coating was mainly evaporated, the uncoated glass surface exhibited a crumbling associated with production of glass powder. This was confirmed by electron microscopy observations. The measured acoustic signal followed the behavior of the emission intensity of the Sn line and was supposed to be proportional to the amount of Sn vapors. The emission intensity depth profile of the Sn coating with graded structure was obtained, which qualitatively corresponded with the depth profile measured by secondary ion mass spectrometry.
Abstract (in Czech)
A pulsed, frequency-quadrupled Nd:YAG laser (266 nm, 10 Hz) coupled to an inductively coupled plasma atomic emission spectrometer (ICP-AES) was employed for depth profiling by ablation of a pyrolytically deposited Sn layer (300 nm) on float glass. The procedure consisted of performing individual ablation cycles (layer-by-layer). A raster with stroke distance of either 50 mu m or 200 mu m (the raster density) was used as an ablation pattern. The ablation was stopped after each cycle and the peal; area of the resulting transient optical signal of the ICP discharge was plotted against the cycle number. The ablation rate of 90 to 20 nm per cycle at a low-energy pulse (6 mJ to 1 mJ) was determined by profilometry. A beam masking was employed to attenuate the laser shot energy and to eliminate the peripheral irregularity of the beam profile. Almost uniform removal of the square area (1 mm x 1 mm) of the coating by ablation was achieved by combining the fitted raster density, beam masking, focusing and beam energy. Different ablation processes were distinguished in cases of the tin coating and the uncoated glass surface. While the coating was mainly evaporated, the uncoated glass surface exhibited a crumbling associated with production of glass powder. This was confirmed by electron microscopy observations. The measured acoustic signal followed the behavior of the emission intensity of the Sn line and was supposed to be proportional to the amount of Sn vapors. The emission intensity depth profile of the Sn coating with graded structure was obtained, which qualitatively corresponded with the depth profile measured by secondary ion mass spectrometry.
Links
GA203/97/0345, research and development projectName: Charakterizace speciálních materiálů pro moderní technologie
Investor: Czech Science Foundation, Characterization of advanced materials for high technology
VS97020, research and development projectName: Laboratoř plazmových zdrojů pro chemickou analýzu
Investor: Ministry of Education, Youth and Sports of the CR, Laboratory of plasma sources for chemical analysis
PrintDisplayed: 7/5/2024 09:10