201. Image quality of microns-thick specimens in the ultra-high voltage electron microscope
- Author
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Fang Wang, Meng Cao, Hai-Bo Zhang, Ryuji Nishi, and Akio Takaoka
- Subjects
Materials science ,Scattering ,business.industry ,Image quality ,General Physics and Astronomy ,Cell Biology ,Electron ,Acceleration voltage ,law.invention ,Optics ,Electron tomography ,Structural Biology ,law ,General Materials Science ,Electron microscope ,business ,High voltage electron microscopy ,Voltage - Abstract
Image quality of MeV transmission electrons is an important factor for both observation and electron tomography of microns-thick specimens with the high voltage electron microscope (HVEM) and the ultra-HVEM. In this work, we have investigated image quality of a tilted thick specimen by experiment and analysis. In a 3 MV ultra-HVEM, we obtained transmission electron images in amplitude contrast of 100 nm gold particles on the top surface of a tilted 5 microm thick amorphous epoxy-resin film. From line profiles of the images, we then measured and evaluated image blurring, contrast, and the signal-to-noise ratio (SNR) under different effective thicknesses of the tilted specimen and accelerating voltages of electrons. The variation of imaging blurring was consistent with the analysis based on multiple elastic scattering. When the effective thickness almost tripled, image blurring increased from approximately 3 to approximately 20 nm at the accelerating voltage of 3 MV. For the increase of accelerating voltage from 1 to 3 MV in the condition of the 14.6 microm effective thickness, due to the reduction of multiple scattering effects, image blurring decreased from approximately 54 to approximately 20 nm, and image contrast and SNR were both obviously enhanced by a factor of approximately 3 to preferable values. The specimen thickness was shown to influence image quality more than the accelerating voltage. Moreover, improvement on image quality of thick specimens due to increasing the accelerating voltage would become less when it was further increased from 2 to 3 MV in this work.
- Published
- 2010
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