Your search keyword '"Biagioni Paolo"' showing total 130 results

1. Strong coupling in metal-semiconductor microcavities featuring Ge quantum wells: a perspective study

Author

Faverzani Marco, Calcaterra Stefano, Biagioni Paolo, and Frigerio Jacopo

Subjects

strong coupling, quantum wells, germanium, Physics, QC1-999

Abstract

In this work we theoretically investigate the possibility of observing strong coupling at mid-infrared frequencies within the group-IV semiconductor material platform. Our results show that the strong coupling condition is attainable in Ge/SiGe quantum wells integrated in hybrid metal-semiconductor microcavities, featuring a highly n-doped SiGe layer as one of the mirrors.

Published

2024

2. Structural and optical characterization of hole-doped Ge/SiGe multiple quantum wells for mid-infrared photonics

Author

Faverzani Marco, Calcaterra Stefano, Impelluso Davide, Giani Raffaele, Bae Jin-Hee, Buca Dan, Virgilio Michele, Chrastina Daniel, Biagioni Paolo, and Frigerio Jacopo

Subjects

Physics, QC1-999

Abstract

The structural and optical properties of p-doped Ge quantum wells separated by SiGe barriers are presented. The composition profile was determined by atom probe tomography and X-ray diffraction measurements. The energy and broadening of the fundamental intersubband transition were studied by Fourier transform infrared spectroscopy which revealed a strong absorption peak around 8.5 μm making this or similar heterostructures suitable for the realization of optoelectronic devices working in the fingerprint region.

Published

2024

3. Polarization-resolved surface-enhanced sensing of single-stranded DNA with Bloch surface waves

Author

Mogni Erika, Pellegrini Giovanni, Gil-Rostra Jorge, Yubero Francisco, Celebrano Michele, Finazzi Marco, Schmidt Katharina, Fossati Stefan, Biagioni Paolo, and Dostálek Jakub

Subjects

Physics, QC1-999

Abstract

We describe a novel one-dimensional photonic crystal design allowing for the concurrent excitation of transverse-electric and transverse-magnetic Bloch surface waves, thus paving the way for polarization-resolved sensing experiments. We discuss its application for the surface-enhanced sensing of oriented DNA molecules through nanoscale birefringence measurements.

Published

2024

4. Strong coupling between photonic modes of stripe microcavities and intersubband transitions in Ge/SiGe multiple quantum wells

Author

Faverzani Marco, Calcaterra Stefano, Biagioni Paolo, and Frigerio Jacopo

Subjects

Physics, QC1-999

Abstract

In this work, we assessed by means of numerical simulations the observability of mid-infrared intersubband polaritons in hole-doped Ge/SiGe multiple quantum wells embedded into stripe microcavities consisting of an upper gold grating and a bottom highly n-doped SiGe mirror.

Published

2024

5. Derivative-free optimization for optical chirality enhancement

Author

Pellegrini Giovanni, Michelotti Francesco, Occhicone Agostino, Celebrano Michele, Finazzi Marco, and Biagioni Paolo

Subjects

Physics, QC1-999

Abstract

We adopt a multi-objective optimization approach to design one-dimensional photonic crystals with large optical chirality enhancements. We show that this technique allows for a large design flexibility in terms of selected materials and operational wavelengths. Finally, we demonstrate that the designed platforms provide state of the art chirality enhancements above the two orders of magnitude over arbitrarily large areas and broad spectral ranges.

Published

2024

6. Germanium Fabry-Perot nanoresonators investigated by cathodoluminescence spectroscopy

Author

Mignuzzi Sandro, Wu Xiaofei, Hecht Bert, Frigerio Jacopo, Isella Giovanni, Celebrano Michele, Finazzi Marco, Sapienza Riccardo, and Biagioni Paolo

Subjects

dielectric nanoantennas, cathodoluminescence spectroscopy, germanium, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

We report on the experimental investigation, by means of spatially-resolved cathodoluminescence spectroscopy, of rectangular all-dielectric Ge nanoantennas sustaining Fabry-Perot resonances. The combination of spatial and spectral resolution allows us to directly image the standing-wave pattern of the local density of optical states inside the nanoantennas, which is the fingerprint of the resonant Purcell contribution to the overall emission enhancement previously reported in the literature for the same structures. Our results confirm that the emission properties of Ge nanostructures can be effectively tuned by engineering the local density of optical states and that cathodoluminescence provides valuable information to experimentally address such modulation in their emission properties.

Published

2024

7. Towards the epitaxial growth of Au thin films on MgO substrates for plasmonic applications

Author

Celebrano Michele, Savoini Matteo, Biagioni Paolo, Della Valle Giuseppe, Pellegrini Giovanni, Cantoni Matteo, Rinaldi Christian, Cattoni Andrea, Petti Daniela, Bertacco Riccardo, Duò Lamberto, and Finazzi Marco

Subjects

surface plasmon polaritons, gold, single crystals, Applied optics. Photonics, TA1501-1820, Optics. Light, QC350-467

Abstract

Surface Plasmon Polaritons (SPPs) in Au thin films are nowadays intensively exploited for sensing applications that leverage the strong optical field confinement at the metal/dielectric interface and the easy functionalization of the Au surface. Moreover, Au thin films represent one of the common starting points for the top-down nanofabrication of plasmonic nanostructures supporting localized resonances. In this framework, strategies for the growth of high-quality Au films on transparent substrates are crucial and not yet fully established. In this study, we exploit MgO(001) substrates for the growth of thin (about 45 nm) Au films, also including an additional buffer layer of Fe. We successfully demonstrate Au samples with reduced roughness and presenting Low-Energy Electron Diffraction (LEED) features, indicating a high degree of crystalline ordering. This is supported by the experimental evidence of an increased (by almost a factor of 3) propagation length compared to a reference Au sample grown on standard glass slides, which is however still significantly lower than the one expected from first principles.

Published

2024

8. Surface vs bulk contribution to the second-harmonic generation in AlGaAs nanoresonators

Author

Luan Yigong, Di Francescantonio Agostino, Zilli Attilio, Rocco Davide, Vinel Vincent, Borne Adrien, Lemaître Aristide, Biagioni Paolo, Duò Lamberto, Finazzi Marco, De Angelis Costantino, Leo Giuseppe, and Celebrano Michele

Subjects

Physics, QC1-999

Abstract

We address the surface vs bulk origin of the second-order optical nonlinearity in AlGaAs nanocylinders through polarization-resolved measurements. By comparing numerical simulations accounting just for bulk second-order nonlinearity with experimental results, we show that the surface contribution to second-harmonic generation (SHG) cannot be neglected and depends on the resonant conditions of the nanocylinder. Additionally, our analysis suggests that bulk and surface SHG are competing effects, and that their interference might influence the overall efficiency.

Published

2023

9. Coherent all-optical steering of upconverted light by a nonlinear metasurface

Author

Di Francescantonio Agostino, Zilli Attilio, Rocco Davide, Conti Fabrizio, Lemaître Aristide, Biagioni Paolo, Duò Lamberto, De Angelis Costantino, Leo Giuseppe, Finazzi Marco, and Celebrano Michele

Subjects

Physics, QC1-999

Abstract

In recent years a strong drive towards the miniaturization of nonlinear optics has been motivated by the functionalities it could empower in integrated devices. Among these, the upconversion of near-infrared photons to the visible and their manipulation is fundamental to downscale optical information. We propose a dual-beam scheme whereby a pulse at the telecom frequency ω (1550 nm wavelength) is mixed with its frequency-doubled replica at 2ω. When the two pump pulses are superimposed on a nonlinear, all-dielectric metasurface two coherent frequency-tripling pathways are excited: third-harmonic generation (THG, ω+ω+ω) and sum-frequency generation (SFG, ω+2ω). Their coherent superposition at 3ω produces interference, which we enable by filtering the k-space with the metasurface diffraction. The steering of the emission among diffraction orders, is sensitive to the relative phase between the two pumps. Therefore, by exploiting the phase as a tuning knob, the upconverted signal can be switched between diffraction orders with an efficiency >90%. The proposed approach can be envisioned as an all-optical method to reroute upconverted telecom photons.

Published

2023

10. Semiconductor infrared plasmonics

Author

Taliercio Thierry and Biagioni Paolo

Subjects

plasmonics, heavily doped semiconductors, infrared spectroscopy, nanoantennas, biosensing, active plasmonics, Physics, QC1-999

Abstract

The coupling between light and collective oscillations of free carriers at metallic surfaces and nanostructures is at the origin of one of the main fields of nanophotonics: plasmonics. The potential applications offered by plasmonics range from biosensing to solar cell technologies and from nonlinear optics at the nanoscale to light harvesting and extraction in nanophotonic devices. Heavily doped semiconductors are particularly appealing for the infrared spectral window due to their compatibility with microelectronic technologies, which paves the way toward their integration in low-cost, mass-fabricated devices. In addition, their plasma frequency can be tuned chemically, optically, or electrically over a broad spectral range. This review covers the optical properties of the heavily doped conventional semiconductors such as Ge, Si, or III–V alloys and how they can be successfully employed in plasmonics. The modeling of their specific optical properties and the technological processes to realize nanoantennas, slits, or metasurfaces are presented. We also provide an overview of the applications of this young field of research, mainly focusing on biosensing and active devices, among the most recent developments in semiconductor plasmonics. Finally, an outlook of further research directions and the potential technological transfer is presented.

Published

2019

11. One-dimensional photonic crystal for polarization-sensitive surface-enhanced spectroscopy

Author

Mogni Erika, Pellegrini Giovanni, Gil-Rostra Jorge, Yubero Francisco, Simone Giuseppina, Fossati Stefan, Dostálek Jakub, Martinez-Vazquez Rebeca, Osellame Roberto, Celebrano Michele, Finazzi Marco, and Biagioni Paolo

Subjects

Physics, QC1-999

Abstract

We realize and experimentally characterize a novel platform for surface-enhanced sensing through Bloch Surface Waves (BSWs). We test a one-dimensional photonic crystal, with a high index inclusion in the top layer, that sustains surfaces modes with, in principle, arbitrary polarization. This is achieved through the coherent superposition of TE and TM dispersion relations of BSWs, which can also provide superchiral fields over a wide spectral range (down to the UV). The resulting platform paves the way to the implementation of polarization-resolved surface-enhanced techniques.

Published

2022

12. Origin of optical nonlinearity in plasmonic semiconductor nanostructures

Author

Rossetti, Andrea, Hu, Huatian, Venanzi, Tommaso, Bousseksou, Adel, De Luca, Federico, Deckert, Thomas, Giliberti, Valeria, Pea, Marialilia, Sagnes, Isabelle, Beaudoin, Gregoire, Biagioni, Paolo, Baù, Enrico, Maier, Stefan A., Tittl, Andreas, Brida, Daniele, Colombelli, Raffaele, Ortolani, Michele, and Ciracì, Cristian

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The development of nanoscale nonlinear elements in photonic integrated circuits is hindered by the physical limits to the nonlinear optical response of dielectrics, which requires that the interacting waves propagate in transparent volumes for distances much longer than their wavelength. Here we present experimental evidence that optical nonlinearities in doped semiconductors are due to free-electron and their efficiency could exceed by several orders of magnitude that of conventional dielectric nonlinearities. Our experimental findings are supported by comprehensive computational results based on the hydrodynamic modeling, which naturally includes nonlocal effects, of the free-electron dynamics in heavily doped semiconductors. By studying third-harmonic generation from plasmonic nanoantenna arrays made out of heavily n-doped InGaAs with increasing levels of free-carrier density, we discriminate between hydrodynamic and dielectric nonlinearities. As a result, the value of maximum nonlinear efficiency as well as its spectral location can now be controlled by tuning the doping level. Having employed the common material platform InGaAs/InP that supports integrated waveguides, our findings pave the way for future exploitation of plasmonic nonlinearities in all-semiconductor photonic integrated circuits.

Published

2024

13. Design of erbium doped silicon nanocavities for single photon applications

Author

Di Giancamillo Matteo, Biagioni Paolo, Sorianello Vito, and Prati Enrico

Subjects

Physics, QC1-999

Abstract

Silicon-based quantum communication technologies are becoming a factual reality. However, the challenges related to an earth-space unifying technology are several, and nowadays an integrated source compatible with the CMOS technology is still missing. Here we present the design of a weak photon source consisting of a LED able to emit directly into the optical circuit and obtained through the doping of a portion of a silicon waveguide with ErOx complexes. To enhance the radiative emission, the source is placed inside a resonant cavity delimited by two waveguide Bragg mirrors. A study on the performance of the device is carried out as a function of different parameters, such as the geometry of the cavity and of the contacts used to electrically excite the defects, the doping level, and the characteristics of the mirrors. We design a prototype that guarantees a Purcell factor in the order of tens, emitting ideally 107-108 photons per second. The simulations provide a promising ground to further develop fully integrated single photon sources in silicon photonic circuits.

Published

2021

14. All-optical free-space routing of upconverted light by metasurfaces via nonlinear interferometry

Author

Di Francescantonio, Agostino, Zilli, Attilio, Rocco, Davide, Coudrat, Laure, Conti, Fabrizio, Biagioni, Paolo, Duò, Lamberto, Lemaître, Aristide, De Angelis, Costantino, Leo, Giuseppe, Finazzi, Marco, and Celebrano, Michele

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

All-optical modulation yields the promise of high-speed information processing. In this frame, metasurfaces are rapidly gaining traction as ultrathin multifunctional platforms for light management. Among the featured functionalities, they enable light wavefront manipulation and, more recently, demonstrated the ability to perform light-by-light manipulation through nonlinear optical processes. Here, by employing a nonlinear periodic metasurface, we demonstrate all-optical routing of telecom photons upconverted to the visible range. This is achieved via the interference between two frequency-degenerate upconversion processes, namely third-harmonic and sum-frequency generation, stemming from the interaction of a pump pulse with its frequency-doubled replica. By tuning the relative phase and polarization between these two pump beams, and concurrently engineering the nonlinear emission of the individual elements of the metasurfaces (meta-atoms) along with its pitch, we route the upconverted signal among the diffraction orders of the metasurface with a modulation efficiency up to 90%. Thanks to the phase control and the ultrafast dynamics of the underlying nonlinear processes, free-space all-optical routing could be potentially performed at rates close to the employed optical frequencies divided by the quality factor of the optical resonances at play. Our approach adds a further twist to optical interferometry, which is a key-enabling technique in a wide range of applications, such as homodyne detection, radar interferometry, LiDAR technology, gravitational waves detection, and molecular photometry. In particular, the nonlinear character of light upconversion combined with phase sensitivity is extremely appealing for enhanced imaging and biosensing., Comment: 18 pages, 6 figures

Published

2023

15. Modelling photothermal induced resonance microscopy: the role of interface thermal resistances

Author

Rusconi, Francesco, Finazzi, Marco, Stormonth-Darling, John M., Mills, Gordon, Badioli, Michela, Baldassarre, Leonetta, Ortolani, Michele, Biagioni, Paolo, and Giliberti, Valeria

Subjects

Condensed Matter - Materials Science

Abstract

Infrared (IR) nanospectroscopy by photothermal induced resonance (PTIR) is a novel experimental technique that combines the nanoscale resolution granted by atomic force microscopy (AFM) and the chemical labelling made possible by IR absorption spectroscopy. While the technique has developed enormously over the last decade from an experimental point of view, the theoretical modelling of the signal still varies significantly throughout the literature and misses a solid benchmark. Here, we report an analysis focused on the electromagnetic and thermal simulations of a PTIR experiment. Thanks to a control experiment where the signal is acquired as a function of the thickness of a polymer film and for different tip geometries, we find clear evidence that the interface thermal resistances play a key role in the determination of the measured signal and should therefore always be accounted for by any quantitative modelling.

Published

2021

16. Tunable broadband light emission from graphene

Author

Ghirardini, Lavinia, Pogna, Eva A. A., Soavi, Giancarlo, Tomadin, Andrea, Biagioni, Paolo, Conte, Stefano Dal, De Fazio, Domenico, Taniguchi, T., Watanabe, K., Duò, Lamberto, Finazzi, Marco, Polini, Marco, Ferrari, Andrea C., Cerullo, Giulio, and Celebrano, Michele

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Graphene is an ideal material for integrated nonlinear optics thanks to its strong light-matter interaction and large nonlinear optical susceptibility. Graphene has been used in optical modulators, saturable absorbers, nonlinear frequency converters, and broadband light emitters. For the latter application, a key requirement is the ability to control and engineer the emission wavelength and bandwidth, as well as the electronic temperature of graphene. Here, we demonstrate that the emission wavelength of graphene$'$ s broadband hot carrier photoluminescence can be tuned by integration on photonic cavities, while thermal management can be achieved by out-of-plane heat transfer to hexagonal boron nitride. Our results pave the way to graphene-based ultrafast broadband light emitters with tunable emission., Comment: 22 pages, 5 Figures

Published

2020

17. Tip-Enhanced Infrared Difference-Nanospectroscopy of the Proton Pump Activity of Bacteriorhodopsin in Single Purple Membrane Patches

Author

Giliberti, Valeria, Polito, Raffaella, Ritter, Eglof, Broser, Matthias, Hegemann, Peter, Puskar, Ljiljana, Schade, Ulrich, Zanetti-Polzi, Laura, Daidone, Isabella, Corni, Stefano, Rusconi, Francesco, Biagioni, Paolo, Baldassarre, Leonetta, and Ortolani, Michele

Subjects

Physics - Biological Physics, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Photosensitive proteins embedded in the cell membrane (about 5 nm thickness) act as photoactivated proton pumps, ion gates, enzymes, or more generally, as initiators of stimuli for the cell activity. They are composed of a protein backbone and a covalently bound cofactor (e.g. the retinal chromophore in bacteriorhodopsin (BR), channel rhodopsin, and other opsins). The light-induced conformational changes of both the cofactor and the protein are at the basis of the physiological functions of photosensitive proteins. Despite the dramatic development of microscopy techniques, investigating conformational changes of proteins at the membrane monolayer level is still a big challenge. Techniques based on atomic force microscopy (AFM) can detect electric currents through protein monolayers and even molecular binding forces in single-protein molecules but not the conformational changes. For the latter, Fourier-transform infrared spectroscopy (FTIR) using difference-spectroscopy mode is typically employed, but it is performed on macroscopic liquid suspensions or thick films containing large amounts of purified photosensitive proteins. In this work, we develop AFM-assisted, tip-enhanced infrared difference-nanospectroscopy to investigate light-induced conformational changes of the bacteriorhodopsin mutant D96N in single submicrometric native purple membrane patches. We obtain a significant improvement compared with the signal-to-noise ratio of standard IR nanospectroscopy techniques by exploiting the field enhancement in the plasmonic nanogap that forms between a gold-coated AFM probe tip and an ultraflat gold surface, as further supported by electromagnetic and thermal simulations. IR difference-spectra in the 1450-1800 cm^{-1} range are recorded from individual patches as thin as 10 nm, with a diameter of less than 500 nm, well beyond the diffraction limit for FTIR microspectroscopy..., Comment: published under ACS AuthorChoice license

Published

2019

18. Plasmonic superchiral lattice resonances in the mid-infrared

Author

Mattioli, Francesco, Mazzeo, Giuseppe, Longhi, Giovanna, Abbate, Sergio, Pellegrini, Giovanni, Celebrano, Michele, Finazzi, Marco, Duò, Lamberto, Zanchi, Chiara, Tommasini, Matteo, Pea, Marialilia, Cibella, Sara, Sciortino, Filippo, Baldassarre, Leonetta, Nucara, Alessandro, Ortolani, Michele, and Biagioni, Paolo

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Recent efforts in the field of surface-enhanced spectroscopies have focused on the paradigm of superchirality, entailing the engineering of the local electromagnetic fields to boost the enantiospecific interaction between light and chiral molecules. In this framework, approaches based on both metallic and dielectric nanostructures have been proposed and have also recently been extended to vibrational circular dichroism in the mid-infrared. In this work, we design, fabricate and characterize arrays of chiral plasmonic slits featuring enhanced chiral fields in the mid-infrared. We exploit collective lattice resonances to further enhance the local intensity and to generate sharp features in the circular dichroism spectra of the platform. Such features are ideally suited to test the superchiral coupling with the vibrational resonances of chiral molecules.

Published

2019

19. Superchiral Surface Waves for All-Optical Enantiomer Separation

Author

Pellegrini, Giovanni, Finazzi, Marco, Celebrano, Michele, duò, Lamberto, Iatì, Maria Antonia, Maragò, Onofrio M., and Biagioni, Paolo

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We introduce the use of superchiral surface waves for the all-optical separation of chiral compounds. Using a combination of electrodynamics modeling and analytical techniques, we show that the proposed approach provides chiral optical forces two orders of magnitude larger than those obtained with circularly polarized plane waves. Superchiral surface waves allow for enantiomer separation on spatial, temporal and size scales than would not be achievable with alternative techniques, thus representing a viable route towards all-optical enantiomer separation.

Published

2018

20. Evidence for cascaded third harmonic generation in non-centrosymmetric gold nanoantennas

Author

Celebrano, Michele, Locatelli, Andrea, Ghirardini, Lavinia, Pellegrini, Giovanni, Biagioni, Paolo, Zilli, Attilio, Wu, Xiaofei, Grossmann, Swen, Carletti, Luca, De Angelis, Costantino, Duò, Lamberto, Hecht, Bert, and Finazzi, Marco

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The optimization of nonlinear optical processes at the nanoscale is a crucial step for the development of nanoscale photon sources for quantum-optical networks. The development of innovative plasmonic nanoantenna designs and hybrid nanostructures to enhance optical nonlinearities in very small volumes represents one of the most promising routes. In such systems, the upconversion of photons can be achieved with high efficiencies via third-order processes, such as third harmonic generation (THG), thanks to the resonantly-enhanced volume currents. Conversely, second-order processes, such as second harmonic generation (SHG), are often inhibited by the symmetry of metal lattices and of common nanoantenna geometries. SHG and THG processes in plasmonic nanostructures are generally treated independently, since they both represent a small perturbation in the light-matter interaction mechanisms. In this work, we demonstrate that this paradigm does not hold in general, by providing evidence of a cascaded process in THG, which is fueled by SHG and sizably contributes to the overall yield. We address this mechanism by unveiling an anomalous fingerprint in the polarization state of the nonlinear emission from non-centrosymmetric gold nanoantennas and point out that such cascaded processes may also appear for structures that exhibit only moderate SHG yields - signifying its general relevance in plasmon-enhanced nonlinear optics. The presence of this peculiar mechanism in THG from plasmonic nanoantennas at telecommunication wavelengths allows gaining further insight on the physics of plasmon-enhanced nonlinear optical processes. This could be crucial in the realization of nanoscale elements for photon conversion and manipulation operating at room-temperature., Comment: 25 pages, 4 figures

Published

2018

21. Mid Infrared Nonlinear Plasmonics using Germanium Nanoantennas on Silicon Substrates

Author

Fischer, Marco P., Riede, Aaron, Gallacher, Kevin, Frigerio, Jacopo, Pellegrini, Giovanni, Ortolani, Michele, Paul, Douglas J., Isella, Giovanni, Leitenstorfer, Alfred, Biagioni, Paolo, and Brida, Daniele

Subjects

Physics - Applied Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We demonstrate third harmonic generation in plasmonic antennas made of highly doped germanium and designed to be resonant in the mid infrared. Owing to the near-field enhancement, the result is an ultrafast, sub-diffraction, coherent light source tunable between 3 and 5 micrometer wavelength on a silicon substrate. To observe nonlinearity in this challenging spectral region, a high-power femtosecond laser system equipped with parametric frequency conversion in combination with an all-reflective confocal microscope setup is employed. We show spatially resolved maps of the linear scattering cross section and the nonlinear emission of single isolated antenna structures. A clear third order power dependence as well as the mid-infrared emission spectra prove the nonlinear nature of the light emission. Simulations support the observed resonance length of the double rod antenna and demonstrate that the field enhancement inside the antenna material is responsible for the nonlinear frequency mixing.

Published

2018

22. Plasmon-enhanced second harmonic sensing

Author

Ghirardini, Lavinia, Baudrion, Anne-Laure, Monticelli, Marco, Petti, Daniela, Biagioni, Paolo, Duò, Lamberto, Pellegrini, Giovanni, Adam, Pierre-Michel, Finazzi, Marco, and Celebrano, Michele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

It has been recently suggested that the nonlinear optical processes in plasmonic nanoantennas allow for a substantial boost in the sensitivity of plasmonic sensing platforms. Here we present a sensing device based on an array of non-centrosymmetric plasmonic nanoantennas featuring enhanced second harmonic generation (SHG) integrated in a microfluidic chip. We evaluate its sensitivity both in the linear and nonlinear regime using a figure of merit (FOM = $(\Delta I/I)/\Delta n$) that accounts for the relative change in the measured intensity, \textit{I}, against the variation of the environmental refractive index \textit{n}. While the signal-to-noise ratio achieved in both regimes allows the detection of a minimum refractive index variation $\Delta n_{min} \approx 10^{-3}$, the platform operation in the nonlinear regime features a sensitivity (i.e. the FOM) that is at least 3 times higher than the linear one. Thanks to the surface sensitivity of plasmon-enhanced SHG, our results show that the development of such SHG sensing platforms with sensitivity performances exceeding those of their linear counterparts is within reach., Comment: 19 Pages, 5 Figures

Published

2017

23. Room-temperature 1.54 $\mu$m photoluminescence of Er:O$_x$ centers at extremely low concentration in silicon

Author

Celebrano, Michele, Ghirardini, Lavinia, Biagioni, Paolo, Finazzi, Marco, Shimizu, Yasuo, Tu, Yuan, Inoue, Koji, Nagai, Yasuyoshi, Shinada, Takahiro, Chiba, Yuki, Abdelghafar, Ayman, Yano, Maasa, Tanii, Takashi, and Prati, Enrico

Subjects

Condensed Matter - Materials Science

Abstract

The demand for single photon sources at $\lambda~=~1.54~\mu$m, which follows from the consistent development of quantum networks based on commercial optical fibers, makes Er:O$_x$ centers in Si still a viable resource thanks to the optical transition of $Er^{3+}~:~^4I_{13/2}~\rightarrow~^4I_{15/2}$. Yet, to date, the implementation of such system remains hindered by its extremely low emission rate. In this Letter, we explore the room-temperature photoluminescence (PL) at the telecomm wavelength of very low implantation doses of $Er:O_x$ in $Si$. The emitted photons, excited by a $\lambda~=~792~nm$ laser in both large areas and confined dots of diameter down to $5~\mu$m, are collected by an inverted confocal microscope. The lower-bound number of detectable emission centers within our diffraction-limited illumination spot is estimated to be down to about 10$^4$, corresponding to an emission rate per individual ion of about $4~\times~10^{3}$ photons/s., Comment: 13 pages, 4 figures

Published

2017

24. Linear and nonlinear optical properties of dewetted SiGe islands

Author

Fagiani, Luca, Granchi, Nicoletta, Zilli, Attilio, Barri, Chiara, Rusconi, Francesco, Montanari, Michele, Mafakheri, Erfan, Celebrano, Michele, Bouabdellaoui, Mohammed, Abbarchi, Marco, Intonti, Francesca, Khursheed, Anjam, Biagioni, Paolo, Finazzi, Marco, Vincenti, Maria Antonietta, and Bollani, Monica

Published

2022

25. Chiral Surface Waves for Enhanced Circular Dichroism

Author

Pellegrini, Giovanni, Finazzi, Marco, Celebrano, Michele, Duò, Lamberto, and Biagioni, Paolo

Subjects

Physics - Optics

Abstract

We present a novel chiral sensing platform that combines a one-dimensional photonic crystal design with a birefringent surface defect. The platform sustains simultaneous transverse electric and transverse magnetic surface modes, which are exploited to generate chiral surface waves. The present design provides homogeneous and superchiral fields of both handednesses over arbitrarily large areas in a wide spectral range, resulting in the enhancement of the circular dichroism signal by two orders of magnitude, thus paving the road toward the successful combination of surface-enhanced spectroscopies and electromagnetic superchirality., Comment: Added references. Corrected typos. Included new design for broadband chiral surface waves

Published

2016

26. Local field enhancement: comparing self-similar and dimer nanoantennas

Author

Pellegrini, Giovanni, Celebrano, Michele, Finazzi, Marco, and Biagioni, Paolo

Subjects

Physics - Optics

Abstract

We study the local field enhancement properties of self-similar nanolenses and compare the obtained results with the performance of standard dimer nanoantennas. We report that, despite the additional structural complexity, self-similar nanolenses are unable to provide significant improvements over the field enhancement performance of standard plasmonic dimers.

Published

2016

27. Optical Activation of Germanium Plasmonic Antennas in the Mid Infrared

Author

Fischer, Marco P., Schmidt, Christian, Sakat, Emilie, Stock, Johannes, Samarelli, Antonio, Frigerio, Jacopo, Ortolani, Michele, Paul, Douglas J., Isella, Giovanni, Leitenstorfer, Alfred, Biagioni, Paolo, and Brida, Daniele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Impulsive interband excitation with femtosecond near-infrared pulses establishes a plasma response in intrinsic germanium structures fabricated on a silicon substrate. This direct approach activates the plasmonic resonance of the Ge structures and enables their use as optical antennas up to the mid-infrared spectral range. The optical switching lasts for hundreds of picoseconds until charge recombination red-shifts the plasma frequency. The full behavior of the structures is modeled by the electrodynamic response established by an electron-hole plasma in a regular array of antennas.

Published

2016

28. Tunability and Losses of Mid-infrared Plasmonics in Heavily Doped Germanium Thin Films

Author

Frigerio, Jacopo, Ballabio, Andrea, Isella, Giovanni, Sakat, Emilie, Biagioni, Paolo, Bollani, Monica, Napolitani, Enrico, Manganelli, Costanza, Virgilio, Michele, Grupp, Alexander, Fischer, Marco P., Brida, Daniele, Gallacher, Kevin, Paul, Douglas J., Baldassarre, Leonetta, Calvani, Paolo, Giliberti, Valeria, Nucara, Alessandro, and Ortolani, Michele

Subjects

Condensed Matter - Materials Science, Condensed Matter - Other Condensed Matter

Abstract

Heavily-doped semiconductor films are very promising for application in mid-infrared plasmonic devices because the real part of their dielectric function is negative and broadly tunable in this wavelength range. In this work we investigate heavily n-type doped germanium epilayers grown on different substrates, in-situ doped in the $10^{17}$ to $10^{19}$ cm$^{-3}$ range, by infrared spectroscopy, first principle calculations, pump-probe spectroscopy and dc transport measurements to determine the relation between plasma edge and carrier density and to quantify mid-infrared plasmon losses. We demonstrate that the unscreened plasma frequency can be tuned in the 400 - 4800 cm$^{-1}$ range and that the average electron scattering rate, dominated by scattering with optical phonons and charged impurities, increases almost linearly with frequency. We also found weak dependence of losses and tunability on the crystal defect density, on the inactivated dopant density and on the temperature down to 10 K. In films where the plasma was optically activated by pumping in the near-infrared, we found weak but significant dependence of relaxation times on the static doping level of the film. Our results suggest that plasmon decay times in the several-picosecond range can be obtained in n-type germanium thin films grown on silicon substrates hence allowing for underdamped mid-infrared plasma oscillations at room temperature., Comment: 18 pages, 10 figures

Published

2016

29. Mid-Infrared Plasmonic Platform based on Heavily Doped Epitaxial Ge-on-Si: Retrieving the Optical Constants of Thin Ge Epilayers

Author

Baldassarre, Leonetta, Calandrini, Eugenio, Samarelli, Antonio, Gallacher, Kevin, Paul, Douglas J., Frigerio, Jacopo, Isella, Giovanni, Sakat, Emilie, Finazzi, Marco, Biagioni, Paolo, and Ortolani, Michele

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science, Physics - Optics

Abstract

The n-type Ge-on-Si epitaxial material platform enables a novel paradigm for plasmonics in the mid-infrared, prompting the future development of lab-on-a-chip and subwavelength vibrational spectroscopic sensors. In order to exploit this material, through proper electrodynamic design, it is mandatory to retrieve the dielectric constants of the thin Ge epilayers with high precision due to the difference from bulk Ge crystals. Here we discuss the procedure we have employed to extract the real and imaginary part of the dielectric constants from normal incidence reflectance measurements, by combining the standard multilayer fitting procedure based on the Drude model with Kramers-Kronig transformations of absolute reflectance data in the zero-transmission range of the thin film., Comment: Infrared, Millimeter, and Terahertz waves (IRMMW-THz), 2014 39th International Conference on

Published

2015

30. Universal Quasi-Static Limit for Plasmon-Enhanced Optical Chirality

Author

Finazzi, Marco, Biagioni, Paolo, Celebrano, Michele, and Duó, Lamberto

Subjects

Condensed Matter - Materials Science, Physics - Optics

Abstract

We discuss the possibility of enhancing the chiroptical response from molecules uniformly distributed around nanostructures that sustain localized plasmon resonances. We demonstrate that the average optical chirality in the near field of any plasmonic nanostrucure cannot be significantly higher than that in a plane wave. This conclusion stems from the quasi-static nature of the nanoparticle-enhanced electromagnetic fields and from the fact that, at optical frequencies, the magnetic response of matter is much weaker than the electric one.

Published

2014

31. Mode-matching in multiresonant plasmonic nanoantennas for enhanced second harmonic generation

Author

Celebrano, Michele, Wu, Xiaofei, Baselli, Milena, Großmann, Swen, Biagioni, Paolo, Locatelli, Andrea, De Angelis, Costantino, Cerullo, Giulio, Osellame, Roberto, Hecht, Bert, Duò, Lamberto, Ciccacci, Franco, and Finazzi, Marco

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics

Abstract

Boosting nonlinear frequency conversion in extremely confined volumes remains a key challenge in nano-optics, nanomedicine, photocatalysis, and background-free biosensing. To this aim, field enhancements in plasmonic nanostructures are often exploited to effectively compensate for the lack of phase-matching at the nanoscale. Second harmonic generation (SHG) is, however, strongly quenched by the high degree of symmetry in plasmonic materials at the atomic scale and in nanoantenna designs. Here, we devise a plasmonic nanoantenna lacking axial symmetry, which exhibits spatial and frequency mode overlap at both the excitation and the SHG wavelengths. The effective combination of these features in a single device allows obtaining unprecedented SHG conversion efficiency. Our results shed new light on the optimization of SHG at the nanoscale, paving the way to new classes of nanoscale coherent light sources and molecular sensing devices based on nonlinear plasmonic platforms., Comment: 14 pages, 4 figures

Published

2014

32. Atomic-scale confinement of optical fields

Author

Kern, Johannes, Grossmann, Swen, Tarakina, Nadezda V., Häckel, Tim, Emmerling, Monika, Kamp, Martin, Huang, Jer-Shing, Biagioni, Paolo, Prangsma, Jord C., and Hecht, Bert

Subjects

Physics - Optics

Abstract

In the presence of matter there is no fundamental limit preventing confinement of visible light even down to atomic scales. Achieving such confinement and the corresponding intensity enhancement inevitably requires simultaneous control over atomic-scale details of material structures and over the optical modes that such structures support. By means of self-assembly we have obtained side-by-side aligned gold nanorod dimers with robust atomically-defined gaps reaching below 0.5 nm. The existence of atomically-confined light fields in these gaps is demonstrated by observing extreme Coulomb splitting of corresponding symmetric and anti-symmetric dimer eigenmodes of more than 800 meV in white-light scattering experiments. Our results open new perspectives for atomically-resolved spectroscopic imaging, deeply nonlinear optics, ultra-sensing, cavity optomechanics as well as for the realization of novel quantum-optical devices.

Published

2011

33. Nanoantennas for visible and infrared radiation

Author

Biagioni, Paolo, Huang, Jer-Shing, and Hecht, Bert

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics, Condensed Matter - Materials Science

Abstract

Nanoantennas for visible and infrared radiation can strongly enhance the interaction of light with nanoscale matter by their ability to efficiently link propagating and spatially localized optical fields. This ability unlocks an enormous potential for applications ranging from nanoscale optical microscopy and spectroscopy over solar energy conversion, integrated optical nanocircuitry, opto-electronics and density-ofstates engineering to ultra-sensing as well as enhancement of optical nonlinearities. Here we review the current understanding of optical antennas based on the background of both well-developed radiowave antenna engineering and the emerging field of plasmonics. In particular, we address the plasmonic behavior that emerges due to the very high optical frequencies involved and the limitations in the choice of antenna materials and geometrical parameters imposed by nanofabrication. Finally, we give a brief account of the current status of the field and the major established and emerging lines of investigation in this vivid area of research., Comment: Review article with 76 pages, 21 figures

Published

2011

34. Atomically flat single-crystalline gold nanostructures for plasmonic nanocircuitry

Author

Huang, Jer-Shing, Callegari, Victor, Geisler, Peter, Brüning, Christoph, Kern, Johannes, Prangsma, Jord C., Wu, Xiaofei, Feichtner, Thorsten, Ziegler, Johannes, Weinmann, Pia, Kamp, Martin, Forchel, Alfred, Biagioni, Paolo, Sennhauser, Urs, and Hecht, Bert

Subjects

Physics - Optics, Condensed Matter - Materials Science, Quantum Physics

Abstract

Deep subwavelength integration of high-definition plasmonic nanostructures is of key importance for the development of future optical nanocircuitry for high-speed communication, quantum computation and lab-on-a-chip applications. So far the experimental realization of proposed extended plasmonic networks consisting of multiple functional elements remains challenging, mainly due to the multi-crystallinity of commonly used thermally evaporated gold layers. Resulting structural imperfections in individual circuit elements will drastically reduce the yield of functional integrated nanocircuits. Here we demonstrate the use of very large (>100 micron^2) but thin (<80 nm) chemically grown single-crystalline gold flakes, which, after immobilization, serve as an ideal basis for focused-ion beam milling and other top-down nanofabrication techniques on any desired substrate. Using this methodology we obtain high-definition ultrasmooth gold nanostructures with superior optical properties and reproducible nano-sized features over micrometer length scales. Our approach provides a possible solution to overcome the current fabrication bottleneck and to realize high-definition plasmonic nanocircuitry., Comment: 28 pages, 14 figures, including Supporting Information (11 pages, 10 figures)

Published

2010

35. Mode imaging and selection in strongly coupled nanoantennas

Author

Huang, Jer-Shing, Kern, Johannes, Geisler, Peter, Weinmann, Pia, Kamp, Martin, Forchel, Alfred, Biagioni, Paolo, and Hecht, Bert

Subjects

Physics - Optics, Physics - Plasma Physics

Abstract

The number of eigenmodes in plasmonic nanostructures increases with complexity due to mode hybridization, raising the need for efficient mode characterization and selection. Here we experimentally demonstrate direct imaging and selective excitation of the bonding and antibonding plasmon mode in symmetric dipole nanoantennas using confocal two-photon photoluminescence mapping. Excitation of a high-quality-factor antibonding resonance manifests itself as a two-lobed pattern instead of the single spot observed for the broad bonding resonance, in accordance with numerical simulations. The two-lobed pattern is observed due to the fact that excitation of the antibonding mode is forbidden for symmetric excitation at the feedgap, while concomitantly the mode energy splitting is large enough to suppress excitation of the bonding mode. The controlled excitation of modes in strongly coupled plasmonic nanostructures is mandatory for efficient sensors, in coherent control as well as for implementing well-defined functionalities in complex plasmonic devices., Comment: 11 pages, 5 figures, 1 supplementary information

Published

2010

36. Temporal and spectral signatures of the interaction between ultrashort laser pulses and Bloch surface waves.

Author

Doughan, Isaac, Asilevi, Atsu L., Halder, Atri, Guo, Tian-Long, Mogni, Erika, Celebrano, Michele, Finazzi, Marco, Pellegrini, Giovanni, Biagioni, Paolo, Descrovi, Emiliano, Roussey, Matthieu, and Turunen, Jari

Subjects

ULTRASHORT laser pulses, BLOCH waves, ULTRA-short pulsed lasers, PHOTONIC crystals

Abstract

The resonant excitation of Bloch Surface Waves (BSWs) in dielectric one-dimensional photonic crystals is becoming a realistic photonic solution for surface integration in many domains, from spectroscopy to local field management. Bringing BSWs to ultrafast and nonlinear regimes requires a deep knowledge of the effects that the photonic crystal dispersion and the resonant surface wave excitation have on the ultrashort laser pulses. We report on the experimental evidence of spectral and temporal modifications of the radiation leaving a planar one-dimensional photonic crystal after coupling to BSWs. In such a resonant condition, a characteristic long temporal tail is observed in the outgoing pulses. Observations are performed by employing both frequency-resolved optical gating and field cross-correlation techniques. [ABSTRACT FROM AUTHOR]

Published

2024

37. Impedance matching and emission properties of optical antennas in a nanophotonic circuit

Author

Huang, Jer-Shing, Feichtner, Thorsten, Biagioni, Paolo, and Hecht, Bert

Subjects

Physics - Optics

Abstract

An experimentally realizable prototype nanophotonic circuit consisting of a receiving and an emitting nano antenna connected by a two-wire optical transmission line is studied using finite-difference time- and frequency-domain simulations. To optimize the coupling between nanophotonic circuit elements we apply impedance matching concepts in analogy to radio frequency technology. We show that the degree of impedance matching, and in particular the impedance of the transmitting nano antenna, can be inferred from the experimentally accessible standing wave pattern on the transmission line. We demonstrate the possibility of matching the nano antenna impedance to the transmission line characteristic impedance by variations of the antenna length and width realizable by modern microfabrication techniques. The radiation efficiency of the transmitting antenna also depends on its geometry but is independent of the degree of impedance matching. Our systems approach to nanophotonics provides the basis for realizing general nanophotonic circuits and a large variety of derived novel devices.

Published

2008

38. All optical sub diffraction multilevel data encoding onto azo polymeric thin films

Author

Savoini, Matteo, Biagioni, Paolo, Duo', Lamberto, and Finazzi, Marco

Subjects

Condensed Matter - Materials Science

Abstract

By exploiting photo-induced reorientation in azo-polymer thin films, we demonstrate all-optical polarization-encoded information storage with a scanning near-field optical microscope. In the writing routine, 5-level bits are created by associating different bit values to different birefringence directions, induced in the polymer after illumination with linearly polarized light. The reading routine is then performed by implementing polarization-modulation techniques on the same near-field microscope, in order to measure the encoded birefringence direction., Comment: 13 pages, 5 figures

Published

2008

39. Chiral optical tweezers for optically active particles in the T-matrix formalism

Author

Patti, Francesco, Saija, Rosalba, Denti, Paolo, Pellegrini, Giovanni, Biagioni, Paolo, Iatì, Maria Antonia, and Maragò, Onofrio M.

Published

2019

40. Plasmonic mid-infrared third harmonic generation in germanium nanoantennas

Author

Fischer, Marco P., Riede, Aaron, Gallacher, Kevin, Frigerio, Jacopo, Pellegrini, Giovanni, Ortolani, Michele, Paul, Douglas J., Isella, Giovanni, Leitenstorfer, Alfred, Biagioni, Paolo, and Brida, Daniele

Published

2018

41. Graphene/Ge microcrystal photodetectors with enhanced infrared responsivity

Author

Falcone, Virginia, primary, Ballabio, Andrea, additional, Barzaghi, Andrea, additional, Zucchetti, Carlo, additional, Anzi, Luca, additional, Bottegoni, Federico, additional, Frigerio, Jacopo, additional, Sordan, Roman, additional, Biagioni, Paolo, additional, and Isella, Giovanni, additional

Published

2022

42. Ge-on-Si Based Mid-infrared Plasmonics

Author

Frigerio, Jacopo, Baldassarre, Leonetta, Pellegrini, Giovanni, Fischer, Marco P., Gallacher, Kevin, Millar, Ross W., Ballabio, Andrea, Brida, Daniele, Isella, Giovanni, Napolitani, Enrico, Paul, Douglas W., Ortolani, Michele, Biagioni, Paolo, Reed, Graham T., and Knights, Andrew P.

Abstract

In the last decade, silicon photonics has undergone an impressive development driven by an increasing number of technological applications. Plasmonics has not yet made its way to the microelectronic industry, mostly because of the lack of compatibility of typical plasmonic materials with foundry processes. In this framework, we have developed a plasmonic platform based on heavily n-doped Ge grown on silicon substrates. We developed growth protocols to reach n-doping levels exceeding 1020 cm-3, allowing us to tune the plasma wavelength of Ge in the 3-15 μm range. The plasmonic resonances of Ge-on-Si nanoantennas have been predicted by simulations, confirmed by experimental spectra and exploited for molecular sensing. Our work represents a benchmark for group-IV mid-IR plasmonics.

Published

2021

43. Field-resolved detection of the temporal response of a single plasmonic antenna in the mid-infrared

Author

Fischer, Marco P., primary, Maccaferri, Nicolò, additional, Gallacher, Kevin, additional, Frigerio, Jacopo, additional, Pellegrini, Giovanni, additional, Paul, Douglas J., additional, Isella, Giovanni, additional, Leitenstorfer, Alfred, additional, Biagioni, Paolo, additional, and Brida, Daniele, additional

Published

2021

44. Supplementary document for Field-resolved detection of the temporal response of a single plasmonic antenna in the mid infrared - 5187862.pdf

Author

Fischer, Marco Patrick, Maccaferri, Nicolò, Gallacher, Kevin, Frigerio, Jacopo, Pellegrini, Giovanni, Paul, Douglas, Isella, Giovanni, Leitenstorfer, Alfred, Biagioni, Paolo, and Brida, Daniele

Abstract

Supplementary figures

Published

2021

45. Field-resolved detection of the temporal response of a single plasmonic antenna in the mid-infrared

Author

Fischer, Marco P., Maccaferri, Nicolò, Gallacher, Kevin, Frigerio, Jacopo, Pellegrini, Giovanni, Paul, Douglas J., Isella, Giovanni, Leitenstorfer, Alfred, Biagioni, Paolo, Brida, Daniele, Fischer, Marco P., Maccaferri, Nicolò, Gallacher, Kevin, Frigerio, Jacopo, Pellegrini, Giovanni, Paul, Douglas J., Isella, Giovanni, Leitenstorfer, Alfred, Biagioni, Paolo, and Brida, Daniele

Abstract

Unveiling the spatial and temporal dynamics of a light pulse interacting with nanosized objects is of extreme importance to widen our understanding of how photons interact with matter at the nanoscale and trigger physical and photochemical phenomena. An ideal platform to study light-matter interactions with an unprecedented spatial resolution is represented by plasmonics, which enables an extreme confinement of optical energy into sub-wavelength volumes. The ability to resolve and control the dynamics of this energy confinement on the time scale of a single optical cycle is at the ultimate frontier towards a full control of nanoscale phenomena. Here, we resolve in the time domain the linear behavior of a single germanium plasmonic antenna in the mid-infrared by measuring the complex optical field response in amplitude and phase with sub-optical-cycle precision, with the promise to extend the observation of light-matter interactions in the time domain to single quantum objects. Accessing this fundamental information opens a plethora of opportunities in a variety of research areas based on plasmon-mediated photonic processes and their coherent control, such as plasmon-enhanced chemical reactions and energy harvesting.

Published

2021

46. Ultrafast generation and control of an electron vortex beam via chiral plasmonic near fields

Author

Vanacore, Giovanni Maria, Berruto, Gabriele, Madan, Ivan, Pomarico, Enrico, Biagioni, Paolo, Lamb, R.J., Reinhardt, O., Kaminer, Ido, Barwick, I, Larocque, Hugo, Grillo, Vincenzo, Karimi, Ebrahim, Garcia de Abajo, F.J., and Carbone, Fabrizio

Subjects

Physics::Optics

Abstract

Imparting orbital angular momentum (OAM) to particle beams opens unique opportunities for applications and exploration of fundamental science. Electron beams carrying OAM are commonly achieved via passive phase masks that imprint a transverse modulation on the particle wave function. Here, we show that a chiral plasmonic near field can be used to generate an OAM-carrying electron beam and dynamically control its vorticity. By monitoring the phase change of the transverse electron wave function in both real space and reciprocal space using ultrafast transmission electron microscopy, we demonstrate that an optically-excited chiral near-field with azimuthal order m = 1 is able to imprint an azimuthally varying 2πℓm phase shift on the electron wave function, where ℓ is the number of exchanged plasmons. In contrast to other passive monolithic methods, our approach enables a dynamic coherent control over the vortex beam properties with attosecond precision. This is achieved by properly modifying the optical field distribution using a sequence of two phase-locked light pulses with independent polarization states and delayed by fractions of their optical cycles. We discuss the potential extension of our method to composite charged particles to yield insights into their inner structure, with particular attention to the proton and the origin of its spin.

Published

2020

47. Generation and control of an ultrafast electron vortex beam via chiral plasmonic near - fields

Author

Vanacore, Giovanni Maria, Berruto, Gabriele, Madan, Ivan, Pomarico, Enrico, Biagioni, Paolo, Lamb, R.J., Reinhardt, O., Kaminer, Ido, Barwick, I, Larocque, Hugo, Grillo, Vincenzo, Karimi, Ebrahim, Garcia de Abajo, F.J., and Carbone, Fabrizio

Subjects

Physics::Optics

Abstract

Imparting orbital angular momentum (OAM) to particle beams opens unique opportunities for applications and exploration of fundamental science. Electron beams carrying OAM are commonly achieved via passive phase masks that imprint a transverse modulation on the particle wave function. Here, we show that a chiral plasmonic near field can be used to generate an OAM-carrying electron beam and dynamically control its vorticity. By monitoring the phase change of the transverse electron wave function in both real space and reciprocal space using ultrafast transmission electron microscopy, we demonstrate that an optically-excited chiral near-field with azimuthal order m = 1 is able to imprint an azimuthally varying 2πℓm phase shift on the electron wave function, where ℓ is the number of exchanged plasmons. In contrast to other passive monolithic methods, our approach enables a dynamic coherent control over the vortex beam properties with attosecond precision. This is achieved by properly modifying the optical field distribution using a sequence of two phase-locked light pulses with independent polarization states and delayed by fractions of their optical cycles. We discuss the potential extension of our method to composite charged particles to yield insights into their inner structure, with particular attention to the proton and the origin of its spin.

Published

2020

48. Supplementary document for Broadband control of the optical properties of semiconductors through site-controlled self-assembly of microcrystals - 4722199.pdf

Author

Pedrini, Jacopo, Biagioni, Paolo, Ballabio, Andrea, Barzaghi, Andrea, Bonzi, Maura, Bonera, Emiliano, Isella, Giovanni, and Pezzoli, Fabio

Abstract

Supplemental document containing the report on facet area and the analysis of the reflectivity decrease in pristine etched pillars compared with pillars with overgrown microcrystals.

Published

2020

49. Optical and electronic properties of transparent conducting Ta:TiO2 thin and ultra-thin films: the effect of doping and thickness

Author

Bricchi, Beatrice R., primary, Sygletou, Maria, additional, Ornago, Luca, additional, Terraneo, Giancarlo, additional, Bisio, Francesco, additional, Mancarella, Cristina, additional, Stasi, Lorenzo, additional, Rusconi, Francesco, additional, Mogni, Erika, additional, Ghidelli, Matteo, additional, Biagioni, Paolo, additional, and Li Bassi, Andrea, additional

Published

2021

50. Broadband control of the optical properties of semiconductors through site-controlled self-assembly of microcrystals

Author

Pedrini, Jacopo, primary, Biagioni, Paolo, additional, Ballabio, Andrea, additional, Barzaghi, Andrea, additional, Bonzi, Maura, additional, Bonera, Emiliano, additional, Isella, Giovanni, additional, and Pezzoli, Fabio, additional

Published

2020