Author
Listed:
- Sukrith Dev
(University of Texas at Austin)
- Yinan Wang
(University of Texas at Austin)
- Kyounghwan Kim
(University of Texas at Austin)
- Marziyeh Zamiri
(University of Wisconsin)
- Clark Kadlec
(Sandia National Laboratories)
- Michael Goldflam
(Sandia National Laboratories)
- Samuel Hawkins
(Sandia National Laboratories)
- Eric Shaner
(Sandia National Laboratories)
- Jin Kim
(Sandia National Laboratories)
- Sanjay Krishna
(Ohio State University)
- Monica Allen
(Munitions Directorate, Eglin Air Force Base)
- Jeffery Allen
(Munitions Directorate, Eglin Air Force Base)
- Emanuel Tutuc
(University of Texas at Austin)
- Daniel Wasserman
(University of Texas at Austin)
Abstract
The measurement of minority carrier lifetimes is vital to determining the material quality and operational bandwidth of a broad range of optoelectronic devices. Typically, these measurements are made by recording the temporal decay of a carrier-concentration-dependent material property following pulsed optical excitation. Such approaches require some combination of efficient emission from the material under test, specialized collection optics, large sample areas, spatially uniform excitation, and/or the fabrication of ohmic contacts, depending on the technique used. In contrast, here we introduce a technique that provides electrical readout of minority carrier lifetimes using a passive microwave resonator circuit. We demonstrate >105 improvement in sensitivity, compared with traditional photoemission decay experiments and the ability to measure carrier dynamics in micron-scale volumes, much smaller than is possible with other techniques. The approach presented is applicable to a wide range of 2D, micro-, or nano-scaled materials, as well as weak emitters or non-radiative materials.
Suggested Citation
Sukrith Dev & Yinan Wang & Kyounghwan Kim & Marziyeh Zamiri & Clark Kadlec & Michael Goldflam & Samuel Hawkins & Eric Shaner & Jin Kim & Sanjay Krishna & Monica Allen & Jeffery Allen & Emanuel Tutuc &, 2019.
"Measurement of carrier lifetime in micron-scaled materials using resonant microwave circuits,"
Nature Communications, Nature, vol. 10(1), pages 1-7, December.
Handle:
RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-09602-2
DOI: 10.1038/s41467-019-09602-2
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