Hybrid integrated silicon photonics based on nanomaterials

Domenic Prete; Francesco Amanti; Greta Andrini; Fabrizio Armani; Vittorio Bellani; Vincenzo Bonaiuto; Simone Cammarata; Matteo Campostrini; Samuele Cornia; Thu Ha Dao; Fabio De Matteis; Valeria Demontis; Giovanni Di Giuseppe; Sviatoslav Ditalia Tchernij; Simone Donati; Andrea Fontana; Jacopo Forneris; Roberto Francini; Luca Frontini; Gian Carlo Gazzadi; Roberto Gunnella; Simone Iadanza; Ali Emre Kaplan; Cosimo Lacava; Valentino Liberali; Leonardo Martini; Francesco Marzioni; Claudia Menozzi; Elena Nieto Hernández; Elena Pedreschi; Paolo Piergentili; Paolo Prosposito; Valentino Rigato; Carlo Roncolato; Francesco Rossella; Andrea Salamon; Matteo Salvato; Fausto Sargeni; Jafar Shojaii; Franco Spinella; Alberto Stabile; Alessandra Toncelli; Gabriella Trucco; Valerio Vitali

doi:10.3390/photonics11050418

Hybrid integrated silicon photonics based on nanomaterials

Domenic Prete^*, Francesco Amanti, Greta Andrini, Fabrizio Armani, Vittorio Bellani, Vincenzo Bonaiuto, Simone Cammarata, Matteo Campostrini, Samuele Cornia, Thu Ha Dao, Fabio De Matteis, Valeria Demontis, Giovanni Di Giuseppe, Sviatoslav Ditalia Tchernij, Simone Donati, Andrea Fontana, Jacopo Forneris, Roberto Francini, Luca Frontini, Gian Carlo GazzadiRoberto Gunnella, Simone Iadanza, Ali Emre Kaplan, Cosimo Lacava, Valentino Liberali, Leonardo Martini, Francesco Marzioni, Claudia Menozzi, Elena Nieto Hernández, Elena Pedreschi, Paolo Piergentili, Paolo Prosposito, Valentino Rigato, Carlo Roncolato, Francesco Rossella, Andrea Salamon, Matteo Salvato, Fausto Sargeni, Jafar Shojaii, Franco Spinella, Alberto Stabile, Alessandra Toncelli, Gabriella Trucco, Valerio Vitali

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

2 Citations (Scopus)

2 Downloads (Pure)

Abstract

Integrated photonic platforms have rapidly emerged as highly promising and extensively investigated systems for advancing classical and quantum information technologies, since their ability to seamlessly integrate photonic components within the telecommunication band with existing silicon-based industrial processes offers significant advantages. However, despite this integration facilitating the development of novel devices, fostering fast and reliable communication protocols and the manipulation of quantum information, traditional integrated silicon photonics faces inherent physical limitations that necessitate a challenging trade-off between device efficiency and spatial footprint. To address this issue, researchers are focusing on the integration of nanoscale materials into photonic platforms, offering a novel approach to enhance device performance while reducing spatial requirements. These developments are of paramount importance in both classical and quantum information technologies, potentially revolutionizing the industry. In this review, we explore the latest endeavors in hybrid photonic platforms leveraging the combination of integrated silicon photonic platforms and nanoscale materials, allowing for the unlocking of increased device efficiency and compact form factors. Finally, we provide insights into future developments and the evolving landscape of hybrid integrated photonic nanomaterial platforms.

Original language	English
Article number	418
Pages (from-to)	1-18
Number of pages	18
Journal	Photonics
Volume	11
Issue number	5
DOIs	https://doi.org/10.3390/photonics11050418
Publication status	Published - May 2024
Externally published	Yes

Bibliographical note

Copyright the Author(s) 2024. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

Keywords

integrated silicon photonics
nanostructured materials
hybrid photonic platforms
integrated photonic circuits

Access to Document

10.3390/photonics11050418Licence: CC BY

Publisher version (open access)Final published version, 79.5 MBLicence: CC BY

Cite this

Prete, D., Amanti, F., Andrini, G., Armani, F., Bellani, V., Bonaiuto, V., Cammarata, S., Campostrini, M., Cornia, S., Dao, T. H., De Matteis, F., Demontis, V., Di Giuseppe, G., Ditalia Tchernij, S., Donati, S., Fontana, A., Forneris, J., Francini, R., Frontini, L., ... Vitali, V. (2024). Hybrid integrated silicon photonics based on nanomaterials. Photonics, 11(5), 1-18. Article 418. https://doi.org/10.3390/photonics11050418

@article{7d9bb8e72dff487493cddc5432abaf6a,

title = "Hybrid integrated silicon photonics based on nanomaterials",

abstract = "Integrated photonic platforms have rapidly emerged as highly promising and extensively investigated systems for advancing classical and quantum information technologies, since their ability to seamlessly integrate photonic components within the telecommunication band with existing silicon-based industrial processes offers significant advantages. However, despite this integration facilitating the development of novel devices, fostering fast and reliable communication protocols and the manipulation of quantum information, traditional integrated silicon photonics faces inherent physical limitations that necessitate a challenging trade-off between device efficiency and spatial footprint. To address this issue, researchers are focusing on the integration of nanoscale materials into photonic platforms, offering a novel approach to enhance device performance while reducing spatial requirements. These developments are of paramount importance in both classical and quantum information technologies, potentially revolutionizing the industry. In this review, we explore the latest endeavors in hybrid photonic platforms leveraging the combination of integrated silicon photonic platforms and nanoscale materials, allowing for the unlocking of increased device efficiency and compact form factors. Finally, we provide insights into future developments and the evolving landscape of hybrid integrated photonic nanomaterial platforms.",

keywords = "integrated silicon photonics, nanostructured materials, hybrid photonic platforms, integrated photonic circuits",

author = "Domenic Prete and Francesco Amanti and Greta Andrini and Fabrizio Armani and Vittorio Bellani and Vincenzo Bonaiuto and Simone Cammarata and Matteo Campostrini and Samuele Cornia and Dao, \{Thu Ha\} and \{De Matteis\}, Fabio and Valeria Demontis and \{Di Giuseppe\}, Giovanni and \{Ditalia Tchernij\}, Sviatoslav and Simone Donati and Andrea Fontana and Jacopo Forneris and Roberto Francini and Luca Frontini and Gazzadi, \{Gian Carlo\} and Roberto Gunnella and Simone Iadanza and Kaplan, \{Ali Emre\} and Cosimo Lacava and Valentino Liberali and Leonardo Martini and Francesco Marzioni and Claudia Menozzi and \{Nieto Hern{\'a}ndez\}, Elena and Elena Pedreschi and Paolo Piergentili and Paolo Prosposito and Valentino Rigato and Carlo Roncolato and Francesco Rossella and Andrea Salamon and Matteo Salvato and Fausto Sargeni and Jafar Shojaii and Franco Spinella and Alberto Stabile and Alessandra Toncelli and Gabriella Trucco and Valerio Vitali",

note = "Copyright the Author(s) 2024. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.",

year = "2024",

month = may,

doi = "10.3390/photonics11050418",

language = "English",

volume = "11",

pages = "1--18",

journal = "Photonics",

issn = "2304-6732",

publisher = "Multidisciplinary Digital Publishing Institute (MDPI)",

number = "5",

}

Prete, D, Amanti, F, Andrini, G, Armani, F, Bellani, V, Bonaiuto, V, Cammarata, S, Campostrini, M, Cornia, S, Dao, TH, De Matteis, F, Demontis, V, Di Giuseppe, G, Ditalia Tchernij, S, Donati, S, Fontana, A, Forneris, J, Francini, R, Frontini, L, Gazzadi, GC, Gunnella, R, Iadanza, S, Kaplan, AE, Lacava, C, Liberali, V, Martini, L, Marzioni, F, Menozzi, C, Nieto Hernández, E, Pedreschi, E, Piergentili, P, Prosposito, P, Rigato, V, Roncolato, C, Rossella, F, Salamon, A, Salvato, M, Sargeni, F, Shojaii, J, Spinella, F, Stabile, A, Toncelli, A, Trucco, G & Vitali, V 2024, 'Hybrid integrated silicon photonics based on nanomaterials', Photonics, vol. 11, no. 5, 418, pp. 1-18. https://doi.org/10.3390/photonics11050418

TY - JOUR

T1 - Hybrid integrated silicon photonics based on nanomaterials

AU - Prete, Domenic

AU - Amanti, Francesco

AU - Andrini, Greta

AU - Armani, Fabrizio

AU - Bellani, Vittorio

AU - Bonaiuto, Vincenzo

AU - Cammarata, Simone

AU - Campostrini, Matteo

AU - Cornia, Samuele

AU - Dao, Thu Ha

AU - De Matteis, Fabio

AU - Demontis, Valeria

AU - Di Giuseppe, Giovanni

AU - Ditalia Tchernij, Sviatoslav

AU - Donati, Simone

AU - Fontana, Andrea

AU - Forneris, Jacopo

AU - Francini, Roberto

AU - Frontini, Luca

AU - Gazzadi, Gian Carlo

AU - Gunnella, Roberto

AU - Iadanza, Simone

AU - Kaplan, Ali Emre

AU - Lacava, Cosimo

AU - Liberali, Valentino

AU - Martini, Leonardo

AU - Marzioni, Francesco

AU - Menozzi, Claudia

AU - Nieto Hernández, Elena

AU - Pedreschi, Elena

AU - Piergentili, Paolo

AU - Prosposito, Paolo

AU - Rigato, Valentino

AU - Roncolato, Carlo

AU - Rossella, Francesco

AU - Salamon, Andrea

AU - Salvato, Matteo

AU - Sargeni, Fausto

AU - Shojaii, Jafar

AU - Spinella, Franco

AU - Stabile, Alberto

AU - Toncelli, Alessandra

AU - Trucco, Gabriella

AU - Vitali, Valerio

N1 - Copyright the Author(s) 2024. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.

PY - 2024/5

Y1 - 2024/5

N2 - Integrated photonic platforms have rapidly emerged as highly promising and extensively investigated systems for advancing classical and quantum information technologies, since their ability to seamlessly integrate photonic components within the telecommunication band with existing silicon-based industrial processes offers significant advantages. However, despite this integration facilitating the development of novel devices, fostering fast and reliable communication protocols and the manipulation of quantum information, traditional integrated silicon photonics faces inherent physical limitations that necessitate a challenging trade-off between device efficiency and spatial footprint. To address this issue, researchers are focusing on the integration of nanoscale materials into photonic platforms, offering a novel approach to enhance device performance while reducing spatial requirements. These developments are of paramount importance in both classical and quantum information technologies, potentially revolutionizing the industry. In this review, we explore the latest endeavors in hybrid photonic platforms leveraging the combination of integrated silicon photonic platforms and nanoscale materials, allowing for the unlocking of increased device efficiency and compact form factors. Finally, we provide insights into future developments and the evolving landscape of hybrid integrated photonic nanomaterial platforms.

AB - Integrated photonic platforms have rapidly emerged as highly promising and extensively investigated systems for advancing classical and quantum information technologies, since their ability to seamlessly integrate photonic components within the telecommunication band with existing silicon-based industrial processes offers significant advantages. However, despite this integration facilitating the development of novel devices, fostering fast and reliable communication protocols and the manipulation of quantum information, traditional integrated silicon photonics faces inherent physical limitations that necessitate a challenging trade-off between device efficiency and spatial footprint. To address this issue, researchers are focusing on the integration of nanoscale materials into photonic platforms, offering a novel approach to enhance device performance while reducing spatial requirements. These developments are of paramount importance in both classical and quantum information technologies, potentially revolutionizing the industry. In this review, we explore the latest endeavors in hybrid photonic platforms leveraging the combination of integrated silicon photonic platforms and nanoscale materials, allowing for the unlocking of increased device efficiency and compact form factors. Finally, we provide insights into future developments and the evolving landscape of hybrid integrated photonic nanomaterial platforms.

KW - integrated silicon photonics

KW - nanostructured materials

KW - hybrid photonic platforms

KW - integrated photonic circuits

UR - https://www.scopus.com/pages/publications/85194199217

U2 - 10.3390/photonics11050418

DO - 10.3390/photonics11050418

M3 - Review article

AN - SCOPUS:85194199217

SN - 2304-6732

VL - 11

SP - 1

EP - 18

JO - Photonics

JF - Photonics

IS - 5

M1 - 418

ER -

Hybrid integrated silicon photonics based on nanomaterials

Abstract

Bibliographical note

Keywords

Access to Document

Other files and links

Fingerprint

Cite this