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Experimentally Minimized Contaminative Condition of Carbonaceous Artifacts in Transmission Electron Microscope  

Kim, Young-Min (Korea Basic Science Institute (KBSI))
Choi, Joo-Hyoung (Korea Basic Science Institute (KBSI))
Song, Kyung (Korea Basic Science Institute (KBSI))
Kim, Yang-Soo (Korea Basic Science Institute (KBSI))
Kim, Youn-Joong (Korea Basic Science Institute (KBSI))
Publication Information
Applied Microscopy / v.39, no.1, 2009 , pp. 73-77 More about this Journal
Abstract
Contaminative artifacts such as carbonaceous materials on carbon-coated microgrids are unavoidable, which is induced by electron beam exposure inside electron microscopes. This phenomenon raise a source to produce confusing information to the samples investigated by analytical TEM, which should be alleviated as much as possible. As experimental precautions for reducing this unwanted effect, the use of $LN_2$ cooled anti-contaminator and pre-illumination of electron beam at low magnification can be helpful. Nevertheless, we should be cautious to set an illumination condition for microanalysis because the contaminative effect is dependent with the types of irradiation situations, which is well known to be a decisive factor for causing the carbonaceous artifacts. Accordingly, it is necessary that optimal illumination to minimize the contaminative effect should be selected for improving the accuracy of microanalysis. In this paper, we introduce the practical method to determine the optimal illumination condition by evaluating the contaminative effect as a function of instrumental spot size, which is directly linked with electron current density.
Keywords
Contamination; Carbonaceous artefacts; TEM;
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1 Cairney JM, Munroe PR: Redeposition effects in transmission electron microscope specimens of FeAl-WC composites prepared using a focused ion beam. Micron 34 : 97-107, 2003   DOI   ScienceOn
2 Cheng A, Fellmann D, Pulokas J, Potter CS, Carragher B: Does contamination buildup limit throughput for automated cryoEM? J Struct Bio 154 : 303-311, 2006   DOI   ScienceOn
3 Kim YM, Kang JS, Kim JS, Jeung JM, Lee JY, Kim YJ: Ultrathin carbon support films for high-resolution electron microscopy of nanoparticles. Microsc Microanal 13 : 285-290, 2007   DOI   ScienceOn
4 Diociaiuti M: Electron energy loss spectroscopy microanalysis and imaging in the transmission electron microscope: example of biological applications. J Electron Spect Rel Phenom 143 : 189-203, 2005   DOI   ScienceOn
5 Hren JJ: Barriers of AEM : Contamination and etching. In: Joy DC, Romig AD, Goldstein JI, eds, Principles of Analytical Electron Microscopy. pp. 353-392, Plenum New York, 1989
6 Egerton RF, Malac PLM: Radiation damage in the TEM and SEM. Micron 35 : 399-409, 2004   DOI   ScienceOn
7 Reimer L, Wächter M: Contribution to the contamination problem in transmission electron microscopy. Ultramicroscopy 3 : 169, 1978   DOI   ScienceOn
8 Kim YM, Lee S, Kim YS, Oh SH, Kim YJ, Lee JY: Electron-beam-induced transition aluminas from aluminum trihydroxide. Scripta Mater 59 : 1022-1025, 2008   DOI   ScienceOn
9 Reimer L: Transmission Electron Microscopy-Physics of Image Formation and Microanalysis. 3rd edit. Springer-Verlag, pp. 457-463, 1993
10 Wei XL, Liu Y, Chen Q, Peng LM: Controlling electron-beaminduced carbon deposition on carbon nanotubes by Joule heating. Nanotech 19 : 355304, 2008   DOI   ScienceOn