The influence of illumination conditions in the measurement of built-in electric field at p–n junctions by 4D-STEM

Momentum resolved 4D-STEM, also called center of mass (CoM) analysis, has been used to measure the long range built-in electric field of a silicon p–n junction. The effect of different STEM modes and the trade-off between spatial resolution and electric field sensitivity are studied. Two acquisition...

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Bibliographic Details
Published in:Applied physics letters 2022-09, Vol.121 (12)
Main Authors: da Silva, Bruno C., Momtaz, Zahra S., Bruas, Lucas, Rouviére, Jean-Luc, Okuno, Hanako, Cooper, David, den-Hertog, Martien I.
Format: Article
Language:English
Subjects:
Applied physics
Condensed Matter
Dwell time
Electric fields
Electrical junctions
Electron beams
Materials Science
P-n junctions
Physics
Signal to noise ratio
Spatial resolution
Thermal noise
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Summary:Momentum resolved 4D-STEM, also called center of mass (CoM) analysis, has been used to measure the long range built-in electric field of a silicon p–n junction. The effect of different STEM modes and the trade-off between spatial resolution and electric field sensitivity are studied. Two acquisition modes are compared: nanobeam and low magnification (LM) modes. A thermal noise free Medipix3 direct electron detector with high speed acquisition has been used to study the influence of low electron beam current and millisecond dwell times on the measured electric field and standard deviation. It is shown that LM conditions can underestimate the electric field values due to a bigger probe size used but provide an improvement of almost one order of magnitude on the signal-to-noise ratio, leading to a detection limit of 0.011   MV   cm − 1 . It is observed that the CoM results do not vary with acquisition time or electron dose as low as 24 e−/A2, showing that the electron beam does not influence the built-in electric field and that this method can be robust for studying beam sensitive materials, where a low dose is needed.
ISSN:0003-6951
1077-3118
DOI:10.1063/5.0104861