Issue 21, 2023

Inside a nanocrystal-based photodiode using photoemission microscopy

Abstract

As nanocrystal-based devices gain maturity, a comprehensive understanding of their electronic structure is necessary for further optimization. Most spectroscopic techniques typically examine pristine materials and disregard the coupling of the active material to its actual environment, the influence of an applied electric field, and possible illumination effects. Therefore, it is critical to develop tools that can probe device in situ and operando. Here, we explore photoemission microscopy as a tool to unveil the energy landscape of a HgTe NC-based photodiode. We propose a planar diode stack to facilitate surface-sensitive photoemission measurements. We demonstrate that the method gives direct quantification of the diode's built-in voltage. Furthermore, we discuss how it is affected by particle size and illumination. We show that combining SnO2 and Ag2Te as electron and hole transport layers is better suited for extended-short-wave infrared materials than materials with larger bandgaps. We also identify the effect of photodoping over the SnO2 layer and propose a strategy to overcome it. Given its simplicity, the method appears to be of utmost interest for screening diode design strategies.

Graphical abstract: Inside a nanocrystal-based photodiode using photoemission microscopy

Supplementary files

Article information

Article type
Paper
Submitted
03 Mar 2023
Accepted
26 Apr 2023
First published
27 Apr 2023

Nanoscale, 2023,15, 9440-9448

Inside a nanocrystal-based photodiode using photoemission microscopy

M. Cavallo, R. Alchaar, E. Bossavit, H. Zhang, T. H. Dang, A. Khalili, Y. Prado, M. G. Silly, J. K. Utterback, S. Ithurria, P. Dudin, J. Avila, D. Pierucci and E. Lhuillier, Nanoscale, 2023, 15, 9440 DOI: 10.1039/D3NR00999H

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