Mapping the Photoresponse of Quantum-Dot-Based Photon-Number-Resolving Detectors

Authors

  • Brecca Bettcher University of Wisconsin-La Crosse
  • Trevor Geerdts University of Wisconsin-La Crosse
  • Connor Govin University of Wisconsin-La Crosse
  • Eric Gansen University of Wisconsin-La Crosse

DOI:

https://doi.org/10.17307/wsc.v1i1.348

Keywords:

Photon, Quantum Dot, Detector, Microscopy

Abstract

We report on the spatial uniformity of the photoresponces produced by a quantum dot, optically gated, field-effect transistor (QDOGFET) with photon-number-resolving capabilities. In these devices, a photoresponce is produced when a photon photocharges a quantum dot, altering the current flowing through the transistor. Variation in the photoreponces produced by different quantum dots reduces the photon-number resolution of the QDOGFET. By using an optical scanning microscope (OMS) to spatially resolve the photoresponse and a solid immersion lens (SIL) to enhance the spatial resolution of the OSM, we acquire contour plots depicting the response magnitude and efficiency of the QDOGFET across the active area. In an analysis of the contour plots, we found that the QDOGFET exhibits optimal signal uniformity when operated at low gate voltages.

Author Biographies

Brecca Bettcher, University of Wisconsin-La Crosse

Department of Physics and Astronomy Student

Trevor Geerdts, University of Wisconsin-La Crosse

Department of Physics and Astronomy Student

Connor Govin, University of Wisconsin-La Crosse

Department of Physics and Astronomy Student

Eric Gansen, University of Wisconsin-La Crosse

Department of Physics and Astronomy Professor

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Published

2022-02-25

How to Cite

Bettcher, B., Geerdts, T., Govin, C., & Gansen, E. (2022). Mapping the Photoresponse of Quantum-Dot-Based Photon-Number-Resolving Detectors. Proceedings of the Wisconsin Space Conference, 1(1). https://doi.org/10.17307/wsc.v1i1.348

Issue

2021: Advancing Aerospace with Artificial Intelligence

Section

Physics and Engineering

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