Minimizing electrostatic charging of an aperture used to produce in-focus phase contrast in the TEM

Microfabricated devices designed to provide phase contrast in the transmission electron microscope must be free of phase distortions caused by unexpected electrostatic effects. We find that such phase distortions occur even when a device is heated to 300°C during use in order to avoid the formation...

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Bibliographic Details
Published in:Ultramicroscopy 2013-12, Vol.135, p.6-15
Main Authors: Glaeser, Robert M., Sassolini, Simone, Cambie, Rossana, Jin, Jian, Cabrini, Stefano, Schmid, Andreas K., Danev, Radostin, Buijsse, Bart, Csencsits, Roseann, Downing, Kenneth H., Larson, David M., Typke, Dieter, Han, B.G.
Format: Article
Language:English
Subjects:
Apertures
Carbon - chemistry
Charging
Cryo-EM
Devices
Electrostatics
Formations
Microscopy, Electron, Transmission - instrumentation
Microscopy, Electron, Transmission - methods
Microtechnology
Phase contrast
Phase distortion
Phase plate
Protein Conformation
Static Electricity
Streptavidin - chemistry
Work functions
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Summary:Microfabricated devices designed to provide phase contrast in the transmission electron microscope must be free of phase distortions caused by unexpected electrostatic effects. We find that such phase distortions occur even when a device is heated to 300°C during use in order to avoid the formation of polymerized, carbonaceous contamination. Remaining factors that could cause unwanted phase distortions include patchy variations in the work function of a clean metal surface, radiation-induced formation of a localized oxide layer, and creation of a contact potential between an irradiated area and the surround due to radiation-induced structural changes. We show that coating a microfabricated device with evaporated carbon apparently eliminates the problem of patchy variation in the work function. Furthermore, we show that a carbon-coated titanium device is superior to a carbon-coated gold device, with respect to radiation-induced electrostatic effects. A carbon-coated, hybrid double-sideband/single-sideband aperture is used to record in-focus, cryo-EM images of monolayer crystals of streptavidin. Images showing no systematic phase error due to charging are achievable under conditions of low-dose data collection. The contrast in such in-focus images is sufficient that one can readily see individual streptavidin tetramer molecules. Nevertheless, these carbon-coated devices perform well for only a limited length of time, and the cause of failure is not yet understood. •In-focus phase contrast is achieved with charging-free, single-sideband apertures.•Conformal coating with evaporated carbon avoids patch-potential effects.•Heating above 300°C avoids contamination effects.•Cryo-EM performance is evaluated with streptavidin monolayer crystals.
ISSN:0304-3991
1879-2723
DOI:10.1016/j.ultramic.2013.05.023