Publications

 

2019

N. Lapshina, J. Jeffet, G. Rosenman, Y. Ebenstein, T. Ellenbogen‏, "Single Fluorescent Peptide Nanodots", ACS Photonics 25, 30115-30123 (2019)

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O. Doron, L. Michaeli, and T. Ellenbogen, "Direct and cascaded collective third-harmonic generation in metasurfaces", JOSA B , 36 7 (2019) 

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S. Keren-Zur, M. Tal, S. Fleischer, D.M. Mittleman, T. Ellenbogen,, "Generation of spatiotemporally tailored terahertz wavepackets by nonlinear metasurfaces‏", Nature communications 10 (1), 1778 (2019)

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R. Ditcovski, O. Avayu, T. Ellenbogen‏, T. Ellenbogen,, "Full-color optical combiner based on multilayered metasurface design‏", Advances in Display Technologies IX 10942, 109420S‏ 

 

2018

N. Lapshina, I. I. Shishkin, R. Nandi, R. E. Noskov, H. Barhom, S. Joseph, B. Apter, T. Ellenbogen, A. Natan, P. Ginzburg, N. Amdursky, G. Rosenman, "Bioinspired Amyloid Nanodots with Visible Fluorescence‏‏", Advanced Optical Materials 7 (5), 1801400‏

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M. A. Fernandez-Rodriguez, R. Elnathan, R. Ditcovski, F. Grillo, G.M. Conley, F. Timpu, A. Rauh, K. Geisel, T. Ellenbogen, R. Grange, F. Scheffold, M. Karg, W. Richtering, N.H. Voelcker, L. Isa, "Tunable 2D binary colloidal alloys for soft nanotemplating", Nanoscale 10, 22189-22195

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S. Keren-Zur and T. Ellenbogen, "A  new dimension for nonlinear photonic crystals‏", Nature Photonics 12 (10), 575‏ (2017)

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L. Yadgarov, B. Visic, T. Abir, R. Tenne, A. Yu. Polyakov, R. Levi, T. V. Dolgova, V. V. Zubyuk, A. A. Fedyanin, E. A. Goodilin, T. Ellenbogen, R. Tennea and D. Oron "Strong light-matter interaction in tungsten disulfide nanotubes", Physical Chemistry Chemical Physics (2018) 

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S. Keren-Zur, L. Michaeli, H. Suchowski, T. Ellenbogen, "Shaping light with nonlinear metasurfaces‏", Advances in Optics and Photonics 10 (1), 309-353‏

TOC_KerenZurAOP_2018.jpg
 

2017

R. Ditcovski and T. Ellenbogen, "Spectral shaping of lasing in vertically aligned coupled nanowire lasers", Optics Express 25, 30115-30123 (2017)

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

E. Eizner, K. Akulov, T. Schwartz and , T. Ellenbogen, "Temporal Dynamics of Localized Exciton-Polaritons
in Composite Organic-Plasmonic Metasurfaces", Nano Letters (2017 )

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

E. Panchenko, J. J. Cadusch, O. Avayu, T. Ellenbogen, T. D. James, D. Gomez, A. Roberts, "In Plane Detection of Guided Surface Plasmons for High Speed Optoelectronic Integrated Circuits", Advanced Materials Technologies, 3,1700196 (2017)

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

L. Michaeli, S. Keren-Zur, O. Avayu, H. Suchowski and T. Ellenbogen, "Nonlinear Surface Lattice Resonance in Plasmonic Nanoparticle Arrays", Physical Review Letters 118, 243904 (2017).

TOC_Michaeli_PRL_2017.png

B. Gilboa, C. Lafargue, A. Handelman, L.J. W. Shimon,G. Rosenman, J. Zyss and T. Ellenbogen "Strong Electro-Optic Effect and Spontaneous Domain Formation in Self-Assembled Peptide Structures",
Advanced Science, 1700052 (2017).

TOC_Gilboa_AdvSci_2017.jpg

Ori Avayu, Euclides Almeida, Yehiam Prior and Tal Ellenbogen "Composite functional metasurfaces for multispectral achromatic optics",Nature Communications 8, 14992 (2017)

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2016

S. Keren-Zur, O. Avayu, L. Michaeli, and T. Ellenbogen "Nonlinear beam shaping with plasmonic metasurfaces", ACS Photonics 3, 117-123 (2016)

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M. Rey, R. Elnathan, R. Ditcovski, K. Geisel, M. Zanini, M. A. Fernandez-Rodriguez, V. V. Naik, A. Frutiger, W. Richtering, T. Ellenbogen, N. H. Voelcker, and L. Isa, "Fully Tunable Silicon Nanowire Arrays by Soft Nanoparticle Templating", Nano Letters 16 157-163 (2016)

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2015

E. Eizner, O. Avayu, R. Ditcovski, T. Ellenbogen, "Aluminum Nanoantenna Complexes for Strong Coupling between Excitons and Localized Surface Plasmons", Nano Letters 15, 6215-6221(2015).

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S. Karepov, N. T. Shaked, T. Ellenbogen, "Off-axis interferometer with adjustable fringe contrast based on polarization encoding", Optics Letters 40, 2273-2276(2015)

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N. Segal, S. Keren-Zur, N. Hendler, T. Ellenbogen, "Controlling light with metamaterial-based nonlinear photonic crystals", Nature Photonics 9, 180-184(2015)

O. Avayu, I. Epstein, E. Eizner, T. Ellenbogen, "Polarization controlled coupling and shaping of surface plasmon polaritons by nanoantenna arrays", Optics Letters 40, 1520-1523(2015)

TOC_AvayuOptLet_2015.jpg

O. Eisenbach, O. Avayu, R. Ditcovski, and T. Ellenbogen, "Metasurfaces based dual wavelength diffractive lenses",
Optics Express 23, 3928-3936 (2015)

TOC_EisenbachOptEx_2015.png
 

2014

E. Eizner and T. Ellenbogen, "Local excitation of strongly coupled exciton-surface plasmons polaritons by a single nanoantenna", Applied Physics Letters 104, 223301 (2014)

TOC_XSPP.jpg

O. Avayu, O. Eisenbach, R. Ditcovski and T. Ellenbogen, "Optical Metasurfaces for Polarization Controlled Beam Shaping", Optics Letters 39, 3892-3895 (2014).

TOCmCGH.jpg
 

-2013

R. Ditcovski and T. Ellenbogen, "Spectral shaping of lasing in vertically aligned coupled nanowire lasers", Optics Express 25, 30115-30123 (2017)

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

E. Eizner, K. Akulov, T. Schwartz and , T. Ellenbogen, "Temporal Dynamics of Localized Exciton-Polaritons
in Composite Organic-Plasmonic Metasurfaces", Nano Letters (2017 )

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

E. Panchenko, J. J. Cadusch, O. Avayu, T. Ellenbogen, T. D. James, D. Gomez, and A. Roberts" In-plane Detection of Guided Surface Plasmons for High Speed Optoelectronic Integrated Circuits", Advanced Materials Technologies, 2017.

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

L. Michaeli, S. Keren-Zur, O. Avayu, H. Suchowski and T. Ellenbogen, "Nonlinear Surface Lattice Resonance in Plasmonic Nanoparticle Arrays", Physical Review Letters 118, 243904 (2017).

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

B. Gilboa, C. Lafargue, A. Handelman, L.J. W. Shimon,G. Rosenman, J. Zyss and T. Ellenbogen "Strong Electro-Optic Effect and Spontaneous Domain Formation in Self-Assembled Peptide Structures",
Advanced Science, 1700052 (2017).

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.

Ori Avayu, Euclides Almeida, Yehiam Prior and Tal Ellenbogen "Composite functional metasurfaces for multispectral achromatic optics",Nature Communications 8, 14992 (2017)

This tutorial aims to provide an extensive overview of methods of generating and shaping light at new frequencies by using nonlinear metasurfaces. We first review methods of manipulating light by using linear metasurfaces, on the basis of local control of the amplitude and phase of transmitted and reflected light. To extend these principles to nonlinear metasurfaces, we first introduce the mechanisms and principles underlying nonlinear interactions in metasurfaces. We then show how to use these principles to control the phase, amplitude, and polarization of emitted nonlinear radiation and how, through careful spatial arrangement of single nonlinear elements on a metasurface, it is possible to tailor the shape of the light emitted through nonlinear interaction.