2D-material-enabled multifunctional mid-IR optoelectronics

2D-material-enabled multifunctional mid-IR optoelectronics

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© 2020 SPIE. New narrow-gap two-dimensional (2-D) semiconductors exemplified by black phosphorus and tellurene are promising material candidates for mid-IR optoelectronic devices. In particular, tellurene, atomically thin crystals of elemental tellurium, is an emerging narrow-gap 2-D semiconductor a...

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Bibliographic Details
Main Authors: Deckoff-Jones, Skylar (Author), Wang, Yixiu (Author), Lin, Hongtao (Author), Wu, Wenzhuo (Author), Hu, Juejun (Author)
Other Authors: Massachusetts Institute of Technology. Department of Materials Science and Engineering (Contributor)
Format: Article
Language:English
Published: SPIE, 2022-04-14T19:06:38Z.
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Summary:© 2020 SPIE. New narrow-gap two-dimensional (2-D) semiconductors exemplified by black phosphorus and tellurene are promising material candidates for mid-IR optoelectronic devices. In particular, tellurene, atomically thin crystals of elemental tellurium, is an emerging narrow-gap 2-D semiconductor amenable to scalable solution-based synthesis and large-area deposition. It uniquely combines tunable bandgap energies, high carrier mobility, exceptionally large electro-optic activity, and superior chemical stability, making it a promising and versatile material platform for mid-infrared photonics. Here we discuß the design and experimental realization of integrated photonic devices based on tellurene and other 2-D semiconductors specifically for the mid-IR spectral regime based on a chalcogenide glaß (ChG) photonic platform.

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