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Silicon–germanium receivers for short-wave-infrared optoelectronics and communications

Benedikovic Daniel et al · Wiley · 2020

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Integrated silicon nanophotonics has rapidly established itself as intriguing research field, whose outlets impact numerous facets of daily life. Indeed, nanophotonics has propelled many advances in optoelectronics, information and communication technologies, sensing and energy, to name a few. Silicon nanophotonics aims to deliver compact and high-performance components based on semiconductor chips leveraging mature fabrication routines already developed within the modern microelectronics. However, the silicon indirect bandgap, the centrosymmetric nature of its lattice and its wide transparency window across optical telecommunication wavebands hamper the realization of essential functionalities, including efficient light generation/amplification, fast electro-optical modulation, and reliable photodetection. Germanium, a well-established complement material in silicon chip industry, has a quasi-direct energy band structure in this wavelength domain. Germanium and its alloys are thus the most suitable candidates for active functions, i.e. bringing them to close to the silicon family of nanophotonic devices. Along with recent advances in silicon–germanium-based lasers and modulators, short-wave-infrared receivers are also key photonic chip elements to tackle cost, speed and energy consumption challenges of exponentially growing data traffics within next-generation systems and networks. Herein, we provide a detailed overview on the latest development in nanophotonic receivers based on silicon and germanium, including material processing, integration and diversity of device designs and arrangements. Our Review also emphasizes surging applications in optoelectronics and communications and concludes with challenges and perspectives potentially encountered in the foreseeable future.

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APA 7

al, B. D. E. (2020). Silicon–germanium receivers for short-wave-infrared optoelectronics and communications. https://doi.org/10.1515/nanoph-2020-0547

MLA

al, Benedikovic Daniel et. "Silicon–germanium receivers for short-wave-infrared optoelectronics and communications." 2020. https://doi.org/10.1515/nanoph-2020-0547.

Chicago

al, Benedikovic Daniel et. 2020. "Silicon–germanium receivers for short-wave-infrared optoelectronics and communications.". https://doi.org/10.1515/nanoph-2020-0547.

Harvard

al, B. D. E. 2020, Silicon–germanium receivers for short-wave-infrared optoelectronics and communications, Wiley, available at: https://doi.org/10.1515/nanoph-2020-0547 [Accessed 29 Jun. 2026].

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Título
Silicon–germanium receivers for short-wave-infrared optoelectronics and communications
Autor / colaboradores
Benedikovic Daniel et al
Editorial
Wiley
Año de publicación
2020
ISSN
2192-8606
ISSN
2192-8606
Idioma
eng

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