Quantitative Characterization of Nanometer-Scale Electric Fields via Momentum-Resolved STEM

Quantitative Characterization of Nanometer-Scale Electric Fields via Momentum-Resolved STEM

Most of today’s electronic devices, like solar cells and batteries, are based on nanometer-scale built-in electric fields. Accordingly, characterization of fields at such small scales has become an important task in the optimization of these devices. In this study, with GaAs-based p−n junctions as t...

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Autores principales: Beyer, Andreas, Munde, Manveer Singh, Firoozabadi, Saleh, Heimes, Damien, Grieb, Tim, Rosenauer, Andreas, Müller-Caspary, Knut, Volz, Kerstin
Formato: Artículo
Lenguaje:inglés
Publicado: Philipps-Universität Marburg 2021
Materias:
momentum-resolved STEM
4DSTEM
electric field measurements
Physik
p−n junctions
transmission electron microscopy
Physics
Acceso en línea:Texto Completo PDF
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Sumario:Most of today’s electronic devices, like solar cells and batteries, are based on nanometer-scale built-in electric fields. Accordingly, characterization of fields at such small scales has become an important task in the optimization of these devices. In this study, with GaAs-based p−n junctions as the example, key characteristics such as doping concentrations, polarity, and the depletion width are derived quantitatively using four-dimensional scanning transmission electron microscopy (4DSTEM). The built-in electric fields are determined by the shift they introduce to the center-of-mass of electron diffraction patterns at subnanometer spatial resolution. The method is applied successfully to characterize two p−n junctions with different doping concentrations. This highlights the potential of this method to directly visualize intentional or unintentional nanoscale electric fields in real-life devices, e.g., batteries, transistors, and solar cells.
Descripción Física:8 Seiten
DOI:10.17192/es2021.0026

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