A Rapid Response Thin-Film Plasmonic-Thermoelectric Light Detector

Creators: Pan, Ying; Tagliabue, Giulia; Eghlidi, Hadi; Höller, Christian; Dröscher, Susanne; Hong, Guo; Poulikakos, Dimos

Abstract

Light detection and quantification is fundamental to the functioning of a broad palette of technologies. While expensive avalanche photodiodes and superconducting bolometers are examples of detectors achieving single-photon sensitivity and time resolutions down to the picosecond range, thermoelectric-based photodetectors are much more affordable alternatives that can be used to measure substantially higher levels of light power (few kW/cm^2). However, in thermoelectric detectors, achieving broadband or wavelength-selective performance with high sensitivity and good temporal resolution requires careful design of the absorbing element. Here, combining the high absorptivity and low heat capacity of a nanoengineered plasmonic thin-film absorber with the robustness and linear response of a thermoelectric sensor, we present a hybrid detector for visible and near-infrared light achieving response times of the order of 100 milliseconds, almost four times shorter than the same thermoelectric device covered with a conventional absorber. Furthermore, we show an almost two times higher light-to-electricity efficiency upon replacing the conventional absorber with a plasmonic absorber. With these improvements, which are direct results of the efficiency and ultra-small thickness of the plasmonic absorber, this hybrid detector constitutes an ideal component for various medium-intensity light sensing applications requiring spectrally tailored absorption coatings with either broadband or narrowband characteristics.

Additional Information

© The Author(s) 2016. This work is licensed under a Creative Commons Attribution 4.0 International License. The images or other third party material in this article are included in the article's Creative Commons license, unless indicated otherwise in the credit line; if the material is not included under the Creative Commons license, users will need to obtain permission from the license holder to reproduce the material. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/ Received: 22 June 2016. Accepted: 01 November 2016. Published online: 22 November 2016. Y. Pan acknowledges the State Scholarship Fund of the China Scholarship Council for financial support. The authors thank Dr. Kelly Mauser and Prof. Harry H. Atwater from Laboratories of Applied Physics in California Institute of Technology for the valuable discussion. This work was partially supported by a grant from the Aurel-Stodola-Fonds (ETH-25 11-2) and by a grant from Alstom (SP-ESC-A 02-14). G. Tagliabue acknowledges support from the Swiss National Science Foundation with the Early Postdoc Mobility Fellowship n. P2EZP2_159101. Author Contributions: Y. Pan, G. Tagliabue and H. Eghlidi conceived the sensor idea and designed the experimental set-up. G. Tagliabue designed the plasmonic absorbers and performed the electromagnetic simulations. Y. Pan, C. Höller, H. Eghlidi and G. Hong performed the fabrication and measurements. S. Dröscher provided the expertise for the commercial thermoelectric detectors. D. Poulikakos supervised all aspects of the project and gave scientific and conceptual advice. Y. Pan, G. Tagliabue, H. Eghlidi and D. Poulikakos wrote the paper. All authors contributed to interpreting the results and proofread the manuscript. The authors declare no competing financial interests.

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