Transfer-printing-enabled GeSn flexible resonant-cavity-enhanced photodetectors with strain-amplified mid-infrared optical responses

Mid-infrared (MIR) flexible photodetectors (FPDs) constitute an essential element for wearable applications, including health-care monitoring and biomedical detection. Compared with organic materials, inorganic semiconductors are promising candidates for FPDs owing to their superior performance as w...

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Bibliographic Details
Published in:Nanoscale 2023-05, Vol.15 (17), p.7745-7754
Main Authors: Tai, Yeh-Chen, An, Shu, Huang, Po-Rei, Jheng, Yue-Tong, Lee, Kuo-Chih, Cheng, Hung-Hsiang, Kim, Munho, Chang, Guo-En
Format: Article
Language:English
Subjects:
Amplification
Compressive properties
Intermetallic compounds
Optoelectronics
Organic materials
Organic semiconductors
Photometers
Polyethylene terephthalate
Silicon substrates
Tensile strain
Transfer printing
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Summary:Mid-infrared (MIR) flexible photodetectors (FPDs) constitute an essential element for wearable applications, including health-care monitoring and biomedical detection. Compared with organic materials, inorganic semiconductors are promising candidates for FPDs owing to their superior performance as well as optoelectronic properties. Herein, for the first time, we present the use of transfer-printing techniques to enable a cost-effective, nontoxic GeSn MIR resonant-cavity-enhanced FPDs (RCE-FPDs) with strain-amplified optical responses. A narrow bandgap nontoxic GeSn nanomembrane was employed as the active layer, which was grown on a silicon-on-insulator substrate and then transfer-printed onto a polyethylene terephthalate (PET) substrate, eliminating the unwanted defects and residual compressive strain, to yield the MIR RCE-FPDs. In addition, a vertical cavity was created for the GeSn active layer to enhance the optical responsivity. Under bending conditions, significant tensile strain up to 0.274% was introduced into the GeSn active layer to effectively modulate the band structure, extend the photodetection in the MIR region, and substantially enhance the optical responsivity to 0.292 A W −1 at λ = 1770 nm, corresponding to an enhancement of 323% compared with the device under flat conditions. Moreover, theoretical simulations were performed to confirm the strain effect on the device performance. The results demonstrated high-performance, nontoxic MIR RCE-FPDs for applications in flexible photodetection. A new low-cost, nontoxic, flexible GeSn mid-infrared resonant-cavity-enhanced photodetector with enhanced optical responses via strain and vertical cavity effects is developed to address the need for large-area, integrated mid-infrared flexible optoelectronics.
ISSN:2040-3364
2040-3372
DOI:10.1039/d2nr07107j