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000827189 1001_ $$0P:(DE-Juel1)145413$$aDuchamp, Martial$$b0$$eCorresponding author
000827189 1112_ $$a16th European Microscopy Congress$$cLyon$$d2016-08-28 - 2016-09-02$$wFrance
000827189 245__ $$aAutomated in situ transmission electron microscopy experiments
000827189 260__ $$aWeinheim, Germany$$bWiley-VCH Verlag GmbH & Co. KGaA$$c2016
000827189 29510 $$aEuropean Microscopy Congress 2016: Proceedings
000827189 300__ $$a638 - 639
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000827189 520__ $$aIn situ transmission electron microscopy (TEM) involves the application of a stimulus to a specimen in the TEM while changes to the specimen are recorded using imaging, diffraction or spectroscopic techniques. However, in most previous in situ TEM studies the apparatus that was used to apply a stimulus did not communicate with the software or hardware that was used to control the TEM and collect data.Important criteria for in situ TEM experiments include minimisation of irradiation dose and avoidance of user bias, resulting in the need to work quickly - and ideally in an automated way. A direct interface between a setup used to apply a stimulus and an interface used to control the TEM is therefore crucial. We have implemented plug-ins for Digital Microcrograph (DM), which can be used to communicate directly with a GPIB bus compatible setup (Fig. 1 a) and external Labview-based software that can then be used to control the stimulus applied to the specimen (e.g., temperature regulation). Values of the applied stimulus and signals measured from the specimen are recorded and added to the tags and titles of TEM images.We have studied silicon oxide-based resistive switching devices in situ in the TEM using a movable W needle and recorded bright-field (BF) TEM images with different voltages applied to the specimen (Figs 1 b-d). A DM script was used to apply a voltage ramp and to measure the current flowing through the sample in an automated way for each applied voltage. By using this approach, we were able to follow the formation and destruction of a conductive path across the SiOx layer and to correlate it with a measured change in conductivity.A second experiment involved in situ electrical biasing of a solar cell and recording a map of electron beam induced current (EBIC) inside the TEM. DM plug-ins were used to record the current generated by the electron beam while scanning the active layer of a μc-Si:H solar cell (Fig. 2 a). The same script was used to measure the current across the sample as the electron beam was scanned across the specimen and a voltage applied to the solar cell. Simultaneously acquired scanning TEM and EBIC maps are shown in Figs 2 (c-d).A further in situ TEM experiment performed on a biased solar cell involved the acquisition of off-axis electron holograms to determine changes in electrostatic potential across the active layer. An external stimulus such as an applied bias can be applied to such as specimen to remove the unwanted mean inner potential contribution from the results. For each applied voltage, a hologram was acquired from the area of interest on the specimen, the stage was moved to record a vacuum reference hologram and it was then returned to the same sample area. This approach was used to record a series of amplitude and phase images from electron holograms of an electrically biased Si:H solar cell (Fig. 2 e) and to extract phase profiles across the top ZnO contact, the p-doped Si layer and the amorphous intrinsic layer (top right of Fig. 2 e).We are grateful to Michael Farle and AG Farle at the University of Duisburg-Essen for technical help. We also acknowledge the European Union under the Seventh Framework Programme under a contract for an Integrated Infrastructure Initiative (Reference 312483 ESTEEM2) and the European Research Council for an Advanced Grant (Reference 320832 IMAGINE).
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000827189 7001_ $$0P:(DE-Juel1)164191$$aDufourcq, Gautier$$b2
000827189 7001_ $$0P:(DE-Juel1)159136$$aMigunov, Vadim$$b3
000827189 7001_ $$0P:(DE-Juel1)144121$$aDunin-Borkowski, Rafal$$b4
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