Large Pockels effect in micro- and nanostructured barium titanate integrated on silicon

The electro-optical Pockels effect is an essential nonlinear effect used in many applications. The ultrafast modulation of the refractive index is, for example, crucial to optical modulators in photonic circuits. Silicon has emerged as a platform for integrating such compact circuits, but a strong P...

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Veröffentlicht in:	Nature materials 2019-01, Vol.18 (1), p.42-47
Hauptverfasser:	Abel, Stefan, Eltes, Felix, Ortmann, J. Elliott, Messner, Andreas, Castera, Pau, Wagner, Tino, Urbonas, Darius, Rosa, Alvaro, Gutierrez, Ana M., Tulli, Domenico, Ma, Ping, Baeuerle, Benedikt, Josten, Arne, Heni, Wolfgang, Caimi, Daniele, Czornomaz, Lukas, Demkov, Alexander A., Leuthold, Juerg, Sanchis, Pablo, Fompeyrine, Jean
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Sprache:	eng
Schlagworte:	639/301/1005 639/624/399 639/925/357 639/925/927 Anisotropy Barium Barium titanates Biomaterials Chemistry and Materials Science Circuits Condensed Matter Physics Electric fields Electro-optical effect Ferroelectric materials Ferroelectricity Materials Science Modulation Modulators Nanotechnology Nanotechnology devices Optical and Electronic Materials Photonics Refractivity Silicon
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creator	Abel, Stefan Eltes, Felix Ortmann, J. Elliott Messner, Andreas Castera, Pau Wagner, Tino Urbonas, Darius Rosa, Alvaro Gutierrez, Ana M. Tulli, Domenico Ma, Ping Baeuerle, Benedikt Josten, Arne Heni, Wolfgang Caimi, Daniele Czornomaz, Lukas Demkov, Alexander A. Leuthold, Juerg Sanchis, Pablo Fompeyrine, Jean
description	The electro-optical Pockels effect is an essential nonlinear effect used in many applications. The ultrafast modulation of the refractive index is, for example, crucial to optical modulators in photonic circuits. Silicon has emerged as a platform for integrating such compact circuits, but a strong Pockels effect is not available on silicon platforms. Here, we demonstrate a large electro-optical response in silicon photonic devices using barium titanate. We verify the Pockels effect to be the physical origin of the response, with r 42 = 923 pm V −1 , by confirming key signatures of the Pockels effect in ferroelectrics: the electro-optic response exhibits a crystalline anisotropy, remains strong at high frequencies, and shows hysteresis on changing the electric field. We prove that the Pockels effect remains strong even in nanoscale devices, and show as a practical example data modulation up to 50 Gbit s −1 . We foresee that our work will enable novel device concepts with an application area largely extending beyond communication technologies. Electro-optic modulators based on epitaxial barium titanate (BTO) integrated on silicon exhibit speeds up to 50 Gbit s –1 while the Pockels coefficient of the BTO film is found to be approaching the bulk value.
doi_str_mv	10.1038/s41563-018-0208-0
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Elliott ; Messner, Andreas ; Castera, Pau ; Wagner, Tino ; Urbonas, Darius ; Rosa, Alvaro ; Gutierrez, Ana M. ; Tulli, Domenico ; Ma, Ping ; Baeuerle, Benedikt ; Josten, Arne ; Heni, Wolfgang ; Caimi, Daniele ; Czornomaz, Lukas ; Demkov, Alexander A. ; Leuthold, Juerg ; Sanchis, Pablo ; Fompeyrine, Jean</creator><creatorcontrib>Abel, Stefan ; Eltes, Felix ; Ortmann, J. Elliott ; Messner, Andreas ; Castera, Pau ; Wagner, Tino ; Urbonas, Darius ; Rosa, Alvaro ; Gutierrez, Ana M. ; Tulli, Domenico ; Ma, Ping ; Baeuerle, Benedikt ; Josten, Arne ; Heni, Wolfgang ; Caimi, Daniele ; Czornomaz, Lukas ; Demkov, Alexander A. ; Leuthold, Juerg ; Sanchis, Pablo ; Fompeyrine, Jean</creatorcontrib><description>The electro-optical Pockels effect is an essential nonlinear effect used in many applications. The ultrafast modulation of the refractive index is, for example, crucial to optical modulators in photonic circuits. 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The ultrafast modulation of the refractive index is, for example, crucial to optical modulators in photonic circuits. Silicon has emerged as a platform for integrating such compact circuits, but a strong Pockels effect is not available on silicon platforms. Here, we demonstrate a large electro-optical response in silicon photonic devices using barium titanate. We verify the Pockels effect to be the physical origin of the response, with r 42 = 923 pm V −1 , by confirming key signatures of the Pockels effect in ferroelectrics: the electro-optic response exhibits a crystalline anisotropy, remains strong at high frequencies, and shows hysteresis on changing the electric field. We prove that the Pockels effect remains strong even in nanoscale devices, and show as a practical example data modulation up to 50 Gbit s −1 . We foresee that our work will enable novel device concepts with an application area largely extending beyond communication technologies. 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subjects	639/301/1005 639/624/399 639/925/357 639/925/927 Anisotropy Barium Barium titanates Biomaterials Chemistry and Materials Science Circuits Condensed Matter Physics Electric fields Electro-optical effect Ferroelectric materials Ferroelectricity Materials Science Modulation Modulators Nanotechnology Nanotechnology devices Optical and Electronic Materials Photonics Refractivity Silicon
title	Large Pockels effect in micro- and nanostructured barium titanate integrated on silicon
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