Your search keyword '"Pertsch Thomas"' showing total 1,221 results

1. Second harmonic generation in monolithic gallium phosphide metasurfaces

Author

Yang Muyi, Weissflog Maximilian A., Fedorova Zlata, Barreda Angela I., Börner Stefan, Eilenberger Falk, Pertsch Thomas, and Staude Isabelle

Subjects

gallium phosphide, nonlinear metasurfaces, second harmonic generation, nanofabrication, Physics, QC1-999

Abstract

Gallium phosphide (GaP) offers unique opportunities for nonlinear and quantum nanophotonics due to its wide optical transparency range, high second-order nonlinear susceptibility, and the possibility to tailor the nonlinear response by a suitable choice of crystal orientation. However, the availability of single crystalline thin films of GaP on low index substrates, as typically required for nonlinear dielectric metasurfaces, is limited. Here we designed and experimentally realized monolithic GaP metasurfaces for enhanced and tailored second harmonic generation (SHG). We fabricated the metasurfaces from bulk (110) GaP wafers using electron-beam lithography and an optimized inductively coupled plasma etching process without a hard mask. SHG measurements showed a high NIR-to-visible conversion efficiency reaching up to 10−5, at the same level as typical values for thin-film-based metasurface designs based on III–V semiconductors. Furthermore, using nonlinear back-focal plane imaging, we showed that a significant fraction of the second harmonic was emitted into the zeroth diffraction order along the optical axis. Our results demonstrate that monolithic GaP metasurfaces are a simple and broadly accessible alternative to corresponding thin film designs for many applications in nonlinear nanophotonics.

Published

2024

2. Entangled photon-pair generation in nonlinear thin-films

Author

Santos Elkin A., Weissflog Maximilian A., Pertsch Thomas, Setzpfandt Frank, and Saravi Sina

Subjects

nano-optics, nonlinear sources, fabry–pérot interference, entanglement, Physics, QC1-999

Abstract

We develop a fully vectorial and non-paraxial formalism to describe spontaneous parametric down-conversion in nonlinear thin films. The formalism is capable of treating slabs with a sub-wavelength thickness, describe the associated Fabry–Pérot effects, and even treat absorptive nonlinear materials. With this formalism, we perform an in-depth study of the dynamics of entangled photon-pair generation in nonlinear thin films, to provide a needed theoretical understanding for such systems that have recently attracted much experimental attention as sources of photon pairs. As an important example, we study the far-field radiation properties of photon pairs generated from a high-refractive-index nonlinear thin-film with zinc-blende structure that is deposited on a linear low-refractive-index substrate. In particular, we study the thickness-dependent effect of Fabry–Pérot interferences on the far-field radiation pattern of the photon pairs. We also pay special attention to study of entanglement generation, and find the conditions under which maximally polarization-entangled photon pairs can be generated and detected in such nonlinear thin-films.

Published

2024

3. Directionally tunable co- and counterpropagating photon pairs from a nonlinear metasurface

Author

Weissflog Maximilian A., Ma Jinyong, Zhang Jihua, Fan Tongmiao, Lung Shaun, Pertsch Thomas, Neshev Dragomir N., Saravi Sina, Setzpfandt Frank, and Sukhorukov Andrey A.

Subjects

spdc, nonlinear metasurface, photon pairs, tuning, guided-mode resonance, spatial control, Physics, QC1-999

Abstract

Nonlinear metasurfaces have recently been established as a new platform for generating photon pairs via spontaneous parametric down-conversion. While for classical harmonic generation in metasurfaces a high level of control over all degrees of freedom of light has been reached, this capability is yet to be developed for photon-pair generation. In this work, we theoretically and experimentally demonstrate for the first time precise control of the emission angle of photon pairs generated from a nonlinear metasurface. Our measurements show angularly tunable pair generation with high coincidence-to-accidental ratio for both co- and counterpropagating emission. The underlying principle is the transverse phase matching of guided-mode resonances with strong angular dispersion in a nonlinear metasurface consisting of a silicon dioxide grating on a nonlinear lithium niobate guiding layer. We provide a straightforward design strategy for photon-pair generation in such a device and find very good agreement between the calculations and experimental results. Here, we use all-optical emission angle tuning by means of the pump wavelength; however, the principle could be extended to modulation via the electro-optic effect in lithium niobate. In sum, this work provides an important addition to the toolset of subwavelength thickness photon-pair sources.

Published

2024

4. Tunable high-order harmonic generation in GeSbTe nano-films

Author

Korolev Viacheslav, Sinelnik Artem D., Rybin Mikhail V., Lazarenko Petr, Kushchenko Olga M., Glukhenkaya Victoria, Kozyukhin Sergey, Zuerch Michael, Spielmann Christian, Pertsch Thomas, Staude Isabelle, and Kartashov Daniil

Subjects

high harmonic generation, gst, active nonlinear photonics, phase change material, Physics, QC1-999

Abstract

High-order harmonic generation (HHG) in solids opens new frontiers in ultrafast spectroscopy of carrier and field dynamics in condensed matter, picometer resolution structural lattice characterization and designing compact platforms for attosecond pulse sources. Nanoscale structuring of solid surfaces provides a powerful tool for controlling the spatial characteristics and efficiency of the harmonic emission. Here we study HHG in a prototypical phase-change material Ge2Sb2Te5 (GST). In this material the crystal phase can be reversibly changed between a crystalline and amorphous phase by light or electric current mediated methods. We show that optical phase-switching is fully reversible and allows for dynamic control of harmonic emission. This introduces GST as new addition to materials that enable flexible metasurfaces and photonic structures that can be integrated in devices and allow for ultrafast optical control.

Published

2024

5. Ultrafast Q-boosting in semiconductor metasurfaces

Author

Yang Ziwei, Liu Mingkai, Smirnova Daria, Komar Andrei, Shcherbakov Maxim, Pertsch Thomas, and Neshev Dragomir

Subjects

all-optical modulation, direct bandgap semiconductors, time-variant metasurfaces, Physics, QC1-999

Abstract

All-optical tunability of semiconductor metasurfaces offers unique opportunities for novel time-varying effects, including frequency conversion and light trapping. However, the all-optical processes often induce optical absorption that fundamentally limits the possible dynamic increase of their quality factor (Q-boosting). Here, we propose and numerically demonstrate the concept of large Q-boosting in a single-material metasurface by dynamically reducing its structural anisotropy on a femtosecond timescale. This balance is achieved by excitation with a structured pump and takes advantage of the band-filling effect in a GaAs direct-bandgap semiconductor to eliminate the free-carrier-induced loss. We show that this approach allows a dynamic boosting of the resonance quality factor over orders of magnitude, only limited by the free-carrier relaxation processes. The proposed approach offers complete dynamic control over the resonance bandwidth and opens applications in frequency conversion and light trapping.

Published

2024

6. Direct growth of monolayer MoS2 on nanostructured silicon waveguides

Author

Kuppadakkath Athira, Najafidehaghani Emad, Gan Ziyang, Tuniz Alessandro, Ngo Gia Quyet, Knopf Heiko, Löchner Franz J. F., Abtahi Fatemeh, Bucher Tobias, Shradha Sai, Käsebier Thomas, Palomba Stefano, Felde Nadja, Paul Pallabi, Ullsperger Tobias, Schröder Sven, Szeghalmi Adriana, Pertsch Thomas, Staude Isabelle, Zeitner Uwe, George Antony, Turchanin Andrey, and Eilenberger Falk

Subjects

2d materials, excitonic photoluminescence, integrated photonics, transition metal dichalcogenides, Physics, QC1-999

Abstract

We report for the first time the direct growth of molybdenum disulfide (MoS2) monolayers on nanostructured silicon-on-insulator waveguides. Our results indicate the possibility of utilizing the Chemical Vapour Deposition (CVD) on nanostructured photonic devices in a scalable process. Direct growth of 2D material on nanostructures rectifies many drawbacks of the transfer-based approaches. We show that the van der Waals material grow conformally across the curves, edges, and the silicon–SiO2 interface of the waveguide structure. Here, the waveguide structure used as a growth substrate is complex not just in terms of its geometry but also due to the two materials (Si and SiO2) involved. A transfer-free method like this yields a novel approach for functionalizing nanostructured, integrated optical architectures with an optically active direct semiconductor.

Published

2022

7. Investigation of dipole emission near a dielectric metasurface using a dual-tip scanning near-field optical microscope

Author

Abbasirad Najmeh, Barreda Angela, Arslan Dennis, Steinert Michael, Fasold Stefan, Rockstuhl Carsten, Staude Isabelle, Setzpfandt Frank, and Pertsch Thomas

Subjects

dielectric metasurface, dipole emission, dual-tip snom, green’s function, near-field, partial ldos, Physics, QC1-999

Abstract

A wide variety of near-field optical phenomena are described by the interaction of dipole radiation with a nanophotonic system. The electromagnetic field due to the dipole excitation is associated with the Green’s function. It is of great interest to investigate the dipole interaction with a photonic system and measure the near-field Green’s function and the quantities it describes, e.g., the local and cross density of optical states. However, measuring the near-field Green’s function requires a point-source excitation and simultaneous near-field detection below the diffraction limit. Conventional single-tip near-field optical microscope (SNOM) provides either a point source excitation or amplitude and phase detection with subwavelength spatial resolution. The automated dual-tip SNOM, composed of two tips, has overcome the experimental challenges for simultaneous near-field excitation and detection. Here, we investigate the dipole emission in the near-field of a dielectric metasurface using the automated dual-tip SNOM. We have analyzed the near-field pattern and directional mode propagation depending on the position of the dipole emission relative to the metasurface. This study is one further step toward measuring the dyadic Green’s function and related quantities such as cross density of optical states in complex nanophotonic systems for both visible and near-infrared spectra.

Published

2021

8. Fabrication of low-loss lithium niobate on insulator waveguides on the wafer scale

Author

Younesi, Mohammadreza, Kasebier, Thomas, Elmanov, Ilia, Li, Yang-Teng, Kumar, Pawan, Geiss, Reinhard, Siefke, Thomas, Eilenberger, Falk, Setzpfandt, Frank, Zeitner, Uwe, and Pertsch, Thomas

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

We report on the wafer scale fabrication of single mode low-loss lithium niobate on insulator waveguides utilizing a chemically amplified resist and an optimized dry etching method. The fabricated single mode waveguides are free of residuals and re-deposition, with measured losses for straight waveguides around 2 dB/m (0.02 dB/cm). We present on a method offering advantages for large-scale production due to its cost-effectiveness, faster writing time, and simplified processes. This work holds promise for advancing integrated photonics and optical communication technologies.

Published

2024

9. Beyond dipolar Huygens’ metasurfaces for full-phase coverage and unity transmittance

Author

Rahimzadegan Aso, Arslan Dennis, Dams David, Groner Achim, Garcia-Santiago Xavi, Alaee Rasoul, Fernandez-Corbaton Ivan, Pertsch Thomas, Staude Isabelle, and Rockstuhl Carsten

Subjects

huygens’ metasurface, multipoles expansion method, scattering theory, hologram, duality symmetry, 42.25.-p, 42.70.-a, 78.67.bf, 76.60.gv, Physics, QC1-999

Abstract

Metasurfaces made from densely packed resonant wavelength-scale particles enable abrupt modulation of impinging electromagnetic radiation within an ultrathin surface. Combining duality symmetry of particles and rotational symmetry of their arrangement led to the development of Huygens’ metasurfaces with perfect transmission. However, so far, when identical particles are considered, only their dipolar multipolar contributions are engineered. There, the achievable phase coverage at a fixed wavelength when modifying the period is smaller than 2π, being a clear limitation for applications. To lift such limitation, we consider dipolar-quadrupolar Huygens’ metasurfaces. They consist of scatterers that require a dipolar and a quadrupolar term to capture their response. We show that such metasurfaces offer access to the desired 2π phase coverage while preserving the perfect efficiency when the conditions of duality and symmetry continue to be met. We also propose core-multishell and disk-multiring particles made from realistic materials to meet the requirements and that can be used to build such metasurfaces. Our results are important as a theoretical basis for large-scale fabrications in imaging and integrated optics.

Published

2019

10. Optical characterization of size- and substrate-dependent performance of ultraviolet hybrid plasmonic nanowire lasers

Author

Vitale, Francesco, Church, Stephen A., Repp, Daniel, Sunil, Karthika S., Ziegler, Mario, Diegel, Marco, Dellith, Andrea, Do, Thi-Hien, Lin, Sheng-Di, Huang, Jer-Shing, Pertsch, Thomas, Parkinson, Patrick, and Ronning, Carsten

Subjects

Physics - Optics

Abstract

Nanowire-based plasmonic lasers are now established as nano-sources of coherent radiation, appearing as suitable candidates for integration into next-generation nanophotonic circuitry. However, compared to their photonic counterparts, their relatively high losses and large lasing thresholds still pose a burdening constraint on their scalability. In this study, the lasing characteristics of ZnO nanowires on Ag and Al substrates, operating as optically-pumped short-wavelength plasmonic nanolasers, are systematically investigated in combination with the size-dependent performance of the hybrid cavity. A hybrid nanomanipulation-assisted single nanowire optical characterization combined with high-throughput PL spectroscopy enables the correlation of the lasing characteristics to the metal substrate and the nanowire diameter. The results evidence that the coupling between excitons and surface plasmons is closely tied to the relationship between substrate dispersive behavior and nanowire diameter. Such coupling dictates the degree to which the lasing character, be it more plasmonic- or photonic-like, can define the stimulated emission features and, as a result, the device performance., Comment: 21 pages, 12 figures, journal paper draft

Published

2024

11. Tailoring Magnetic Dipole Emission by Broken-Symmetry TiO2 Metasurfaces

Author

Bashiri Ayesheh, Vaskin Aleksandr, Tanaka Katsuya, Pertsch Thomas, and Staude Isabelle

Subjects

Physics, QC1-999

Abstract

Strong magnetic dipole emission is offered by rare earth ions such as trivalent lanthanides, due to selection rule forbidden electric dipole (ED) transitions. This stimulates the study of optical nanostructures, which efficiently tailor magnetic dipole emission. High refractive index all dielectric nanostructures are promising candidates in this regard due to their strong magnetic response and negligible absorption loss in the visible spectral range. Here, we design and experimentally realize a broken-symmetry titanium dioxide (TiO2) metasurface supporting an out-of-plane magnetic dipole (MD) resonance at 590 nm wavelength, corresponding to the MD transition of trivalent Europium ions (Eu3+). A strong photoluminescence (PL) enhancement of the MD transition up to a factor of 15.5 is observed.

Published

2022

12. Entangled Photon-pair Generation in Nonlinear Thin-films

Author

Santos, Elkin A., Weissflog, Maximilian A., Pertsch, Thomas, Setzpfandt, Frank, and Saravi, Sina

Subjects

Quantum Physics, Physics - Optics

Abstract

We develop a fully vectorial and non-paraxial formalism to describe spontaneous parametric down-conversion in nonlinear thin films. The formalism is capable of treating slabs with a sub-wavelength thickness, describe the associated Fabry-P\'erot effects, and even treat absorptive nonlinear materials. With this formalism, we perform an in-depth study of the dynamics of entangled photon-pair generation in nonlinear thin films, to provide a needed theoretical understanding for such systems that have recently attracted much experimental attention as sources of photon pairs. As an important example, we study the far-field radiation properties of photon pairs generated from a high-refractive-index nonlinear thin-film with Zinc-Blende structure, that is deposited on a linear low-refractive-index substrate. In particular, we study the thickness-dependent effect of Fabry-P\'erot interferences on the far-field radiation pattern of the photon pairs. We also pay special attention to study of entanglement generation, and find the conditions under which maximally polarization-entangled photon pairs can be generated and detected in such nonlinear thin-films.

Published

2024

13. Influence of resonant plasmonic nanoparticles on optically accessing the valley degree of freedom in 2D semiconductors

Author

Bucher, Tobias, Fedorova, Zlata, Abasifard, Mostafa, Mupparapu, Rajeshkumar, Wurdack, Matthias J., Najafidehaghani, Emad, Gan, Ziyang, Knopf, Heiko, George, Antony, Eilenberger, Falk, Pertsch, Thomas, Turchanin, Andrey, and Staude, Isabelle

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

The valley degree of freedom is one of the most intriguing properties of atomically thin transition metal dichalcogenides. Together with the possibility to address this degree of freedom by valley-contrasting optical selection rules, it has the potential to enable a completely new class of future electronic and optoelectronic devices. Resonant optical nanostructures emerge as promising tools for interacting with and controlling the valley degree of freedom at the nanoscale. However, a critical understanding gap remains in how nanostructures and their nearfields affect the circular polarization properties of valley-selective emission hindering further developments in this field. In order to address this issue, our study delves into the experimental investigation of a hybrid model system where valley-specific emission from a monolayer of molybdenum disulfide is interacting with a resonant plasmonic nanosphere. Contrary to the simple intuition suggesting that a centrosymmetric nanoresonator preserves the degree of circular polarization in the forward scattered farfield by angular momentum conservation, our cryogenic photoluminescence microscopy reveals that the light emitted from the nanoparticle position is largely unpolarized, i.e. we observe depolarization. We rigorously study the nature of this phenomenon numerically considering the monolayer-nanoparticle interaction at different levels including excitation and emission. In doing so, we find that the farfield degree of polarization strongly reduces in the hybrid system when including excitons emitting from outside of the system's symmetry point, which in combination with depolarisation at the excitation level causes the observed effect. Our results highlight the importance of considering spatially distributed emitters for precise predictions of polarization responses in these hybrid systems., Comment: Tobias Bucher and Zlata Fedorova contributed equally to this work. 29 pages, 6 figures

Published

2024

14. Nonlocal quantum differentiation between polarization objects using entanglement

Author

Besaga, Vira R., Zhang, Luosha, Vega, Andres, Chauhan, Purujit Singh, Siefke, Thomas, Steinlechner, Fabian, Pertsch, Thomas, Sukhorukov, Andrey A., and Setzpfandt, Frank

Subjects

Quantum Physics, Physics - Optics

Abstract

For a wide range of applications a fast, non-destructive, remote, and sensitive identification of samples with predefined characteristics is preferred instead of their full characterization. Here, we report on the experimental implementation of a nonlocal quantum measurement scheme enabling to distinguish different transparent and birefringent samples by means of polarization-entangled photon pairs and remote state preparation. On an example set of more than 80 objects with varying Mueller matrices we show that only two coincidence measurements are already sufficient for successful discrimination in contrast to at least 8 required for a comprehensive inspection. The decreased number of measurements and the sample set significantly exceeding a typical set size for various problems demonstrate the high potential of the method for applications aiming at biomedical diagnostics, remote sensing, and other classification/detection tasks., Comment: 11 pages, 5 figures

Published

2023

15. A tunable transition metal dichalcogenide entangled photon-pair source

Author

Weissflog, Maximilian A., Fedotova, Anna, Tang, Yilin, Santos, Elkin A., Laudert, Benjamin, Shinde, Saniya, Abtahi, Fatemeh, Afsharnia, Mina, Pérez Pérez, Inmaculada, Ritter, Sebastian, Qin, Hao, Janousek, Jiri, Shradha, Sai, Staude, Isabelle, Saravi, Sina, Pertsch, Thomas, Setzpfandt, Frank, Lu, Yuerui, and Eilenberger, Falk

Published

2024

16. Ultrafast all-optical second harmonic wavefront shaping

Author

Sinelnik, Artem, Lam, Shiu Hei, Coviello, Filippo, Klimmer, Sebastian, Della Valle, Giuseppe, Choi, Duk-Yong, Pertsch, Thomas, Soavi, Giancarlo, and Staude, Isabelle

Published

2024

17. Generation of infrared photon pairs by spontaneous four-wave mixing in a CS2-filled microstructured optical fiber

Author

Afsharnia, Mina, Junaid, Saher, Saravi, Sina, Chemnitz, Mario, Wondraczek, Katrin, Pertsch, Thomas, Schmidt, Markus A., and Setzpfandt, Frank

Published

2024

18. Nonlinear Nanoresonators for Bell State Generation

Author

Weissflog, Maximilian A., Dezert, Romain, Vinel, Vincent, Gigli, Carlo, Leo, Giuseppe, Pertsch, Thomas, Setzpfandt, Frank, Borne, Adrien, and Saravi, Sina

Subjects

Physics - Optics

Abstract

Entangled photon states are a fundamental resource for optical quantum technologies and investigating the fundamental predictions of quantum mechanics. Up to now such states are mainly generated in macroscopic nonlinear optical systems with elaborately tailored optical properties. In this theoretical work, we extend the understanding on the generation of entangled photonic states towards the nanoscale regime, by investigating the fundamental properties of photon-pair-generation in sub-wavelength nonlinear nanoresonators. Taking materials with Zinc-Blende structure as example, we reveal that such systems can naturally generate various polarization-entangled Bell states over a very broad range of wavelengths and emission directions, with little to no engineering needed. Interestingly, we uncover different regimes of operation, where polarization-entangled photons can be generated with dependence on or complete independence from the pumping wavelength and polarization, and the modal content of the nanoresonator. Our work also shows the potential of nonlinear nanoresonators as miniaturized sources of biphoton states with highly complex and tunable properties., Comment: 15 pages, 6 figures

Published

2023

19. Pinhole quantum ghost imaging

Author

Vega, Andres, Saravi, Sina, Pertsch, Thomas, and Setzpfandt, Frank

Subjects

Quantum Physics

Abstract

We propose a quantum ghost imaging scheme based on biphotons, that, by using a collimated pump beam of the right size for biphoton generation, obviates the need for lenses to achieve imaging. The scheme is found to be analogous to the classical pinhole camera, where we show that the equivalent to the classical pinhole size depends mainly on the width of the pump beam, but also on the thickness of the nonlinear crystal and the wavelengths of the biphoton.

Published

2023

20. Sub-minute Quantum Ghost Imaging in the infrared enabled by a 'looking back' SPAD array

Author

Gili, Valerio Flavio, Dupish, Dupish, Vega, Andres, Gandola, Massimo, Manuzzato, Enrico, Perenzoni, Matteo, Gasparini, Leonardo, Pertsch, Thomas, and Setzpfandt, Frank

Subjects

Physics - Optics, Quantum Physics

Abstract

Quantum Ghost Imaging (QGI) is an intriguing imaging protocol that exploits photon-pair correlations stemming from spontaneous parametric down-conversion (SPDC). QGI retrieves images from two-path joint measurements, where single-path detection does not allow to reconstruct the target image. This technique, has been so far limited in terms of acquisition speed either by raster scanning, or by the slow electronics of intensified cameras. Here we report on a fast QGI implementation exploiting a SPAD array detector for the spatially resolving path, enabling the acquisition of a ghost image in under one minute. Moreover, the employment of non-degenerate SPDC allows to investigate samples at infrared wavelengths without the need for short-wave infrared (SWIR) cameras, while the spatial detection can be still performed in the visible region, where the more advanced silicon-based technology can be exploited. Our findings advance the state-of-the-art of QGI schemes towards practical applications.

Published

2022

21. Tailoring Nanowire Lasing Modes via Coupling to Metal Gratings

Author

Vitale, Francesco, Repp, Daniel, Siefke, Thomas, Zeitner, Uwe, Peschel, Ulf, Pertsch, Thomas, and Ronning, Carsten

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Tailoring the emission of plasmonic nanowire-based lasers represents one of the major challenges in the field of nanoplasmonics, given the envisaged integration of such devices into on-chip all-optical circuits. In this study, we proposed a mode selection scheme based on distributed feedback, achieved via the external coupling of single zinc oxide nanowires to an aluminum grating, which enabled a quasi-single mode lasing action. The nano-manipulation of a single nanowire allowed for a reliable comparison of the lasing emission characteristics in both planar (i.e. nanowire on the metallic substrate) and on-grating configurations. We found that, by varying the orientation of the nanowire on the grating, only when the nano-cavity was perpendicular to the ridge direction, an additional peak emerged in the emission spectrum on the low-energy side of the gain envelope. As a consequence of the fulfillment of the Bragg condition, such a peak was attributed to a hybrid mode dominating the mode competition. Simulation results showed that the hybrid mode could be efficiently waveguided along the nanowire cavity and supported by localized plasmon polaritons building up at the raised features ("fences") on top of the metal grating ridges. Moreover, the hybrid mode was found to experience an extra reflectance of nearly 50% across the grating periods, in addition to that provided by the nanowire end facets.

Published

2022

22. Visualizing the ultra-structure of microorganisms using table-top extreme ultraviolet imaging

Author

Liu, Chang, Eschen, Wilhelm, Loetgering, Lars, Molina, Daniel S., Klas, Robert, Iliou, Alexander, Steinert, Michael, Herkersdorf, Sebastian, Kirsche, Alexander, Pertsch, Thomas, Hillmann, Falk, Limpert, Jens, and Rothhardt, Jan

Subjects

Physics - Biological Physics, Physics - Optics

Abstract

Table-top extreme ultraviolet (EUV) microscopy offers unique opportunities for label-free investigation of biological samples. Here, we demonstrate ptychographic EUV imaging of two dried, unstained model specimens: germlings of a fungus (Aspergillus nidulans), and bacteria (Escherichia coli) cells at 13.5 nm wavelength. We find that the EUV spectral region, which to date has not received much attention for biological imaging, offers sufficient penetration depths for the identification of intracellular features. By implementing a position-correlated ptychography approach, we demonstrate a millimeter-squared field of view enabled by infrared illumination combined with sub-60 nm spatial resolution achieved with EUV illumination on selected regions of interest. The strong element contrast at 13.5 nm wavelength enables the identification of the nanoscale material composition inside the specimens. Our work will advance and facilitate EUV imaging applications and enable further possibilities in life science.

Published

2022

23. Lasing modes in ZnO nanowires coupled to planar metals

Author

Repp, Daniel, Barreda, Angela, Vitale, Francesco, Staude, Isabelle, Peschel, Ulf, Ronning, Carsten, and Pertsch, Thomas

Subjects

Physics - Optics

Abstract

Semiconductor nanowire lasers can be subject to modifications of their lasing threshold resulting from a variation of their environment. A promising choice is to use metallic substrates to gain access to low-volume Surface-Plasmon-Polariton (SPP) modes. We introduce a simple, yet quantitatively precise model that can serve to describe mode competition in nanowire lasers on metallic substrates. We show that an aluminum substrate can decrease the lasing threshold for ZnO nanowire lasers while for a silver substrate, the threshold increases compared with a dielectric substrate. Generalizing from these findings, we make predictions describing the interaction between planar metals and semiconductor nanowires, which allow to guide future improvements of highly-integrated laser sources.

Published

2022

24. Meta-Optics with Lithium Niobate

Author

Fedotova, Anna, Carletti, Luca, Zilli, Attilio, Setzpfandt, Frank, Staude, Isabelle, Toma, Andrea, Finazzi, Marco, De Angelis, Costantino, Pertsch, Thomas, Neshev, Dragomir N., and Celebrano, Michele

Subjects

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

Abstract

The rapid development of metasurfaces - 2D ensembles of engineered nanostructures - is presently fostering a steady drive towards the miniaturization of many optical functionalities and devices to a subwavelength size. The material platforms for optical metasurfaces are rapidly expanding and for the past few years, we are seeing a surge in establishing meta-optical elements from high-index, highly transparent materials with strong nonlinear and electro-optic properties. Crystalline lithium niobate (LN), a prime material of choice in integrated photonics, has shown great promise for future meta-optical components, thanks to its large electro-optical coefficient, second-order nonlinear response and broad transparency window ranging from the visible to the mid-infrared. Recent advances in nanofabrication technology have indeed marked a new milestone in the miniaturization of LN platforms, hence enabling the first demonstrations of LN-based metasurfaces. These seminal works set the first steppingstone towards the realization of ultra-flat monolithic nonlinear light sources with emission ranging from the visible to the infrared, efficient sources of correlated photon pairs, as well as electro-optical devices. Here, we review these recent advances, discussing potential perspectives for applications in light conversion and modulation shaping as well as quantum optics, with a critical eye on the potential setbacks and limitations of this emerging field., Comment: 45 Pages, 6 Figures

Published

2022

25. Direct Growth of Monolayer MoS$_2$ on Nanostructured Silicon Waveguides

Author

Kuppadakkath, Athira, Najafidehaghani, Emad, Gan, Ziyang, Tuniz, Alessandro, Ngo, Gia Quyet, Knopf, Heiko, Löchner, Franz J. F., Abtahi, Fatemeh, Bucher, Tobias, Shradha, Sai, Käsebier, Thomas, Palomba, Stefano, Felde, Nadja, Paul, Pallabi, Ullsperger, Tobias, Schröder, Sven, Szeghalmi, Adriana, Pertsch, Thomas, Staude, Isabelle, Zeitner, Uwe, George, Antony, Turchanin, Andrey, and Eilenberger, Falk

Subjects

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

Abstract

We report for the first time the direct growth of Molybdenum disulfide (MoS$_2$) monolayers on nanostructured silicon-on-insulator waveguides. Our results indicate the possibility of utilizing the Chemical Vapour Deposition (CVD) on nanostructured photonic devices in a scalable process. Direct growth of 2D material on nanostructures rectifies many drawbacks of the transfer-based approaches. We show that the van der Waals materials grow conformally across the curves, edges, and the silicon-SiO$_2$ interface of the waveguide structure. Here, the waveguide structure used as a growth substrate is complex not just in terms of its geometry but also due to the two materials (Si and SiO$_2$) involved. A transfer-free method like this yields a novel approach for functionalizing nanostructured, integrated optical architectures with an optically active direct semiconductor.

Published

2022

26. Subdiffraction Quantum Imaging with Undetected Photons

Author

Santos, Elkin A., Pertsch, Thomas, Setzpfandt, Frank, and Saravi, Sina

Subjects

Quantum Physics, Physics - Optics

Abstract

We propose a nonlinear imaging scheme with undetected photons that overcomes the diffraction limit by transferring near-field information at one wavelength to far-field information of a correlated photon with a different wavelength generated through spontaneous photon-pair generation. At the same time, this scheme allows for retrieval of high-contrast images with zero background, making it a highly sensitive scheme for imaging of small objects at challenging spectral ranges with subdiffraction resolutions.

Published

2022

27. Nonlinear quantum spectroscopy with Parity-Time symmetric integrated circuits

Author

Kumar, Pawan, Saravi, Sina, Pertsch, Thomas, Setzpfandt, Frank, and Sukhorukov, Andrey A.

Subjects

Physics - Optics, Quantum Physics

Abstract

We propose a novel quantum nonlinear interferometer design that incorporates a passive PT symmetric coupler sandwiched between two nonlinear sections where signal-idler photon pairs are generated. The PT-symmetry enables efficient coupling of the longer-wavelength idler photons and facilitates the sensing of losses in the second waveguide exposed to analyte under investigation, whose absorption can be inferred by measuring only the signal intensity at a shorter wavelength where efficient detectors are readily available. Remarkably, we identify a new phenomenon of sharp signal intensity fringe shift at critical idler loss values, which is distinct from the previously studied PT-symmetry breaking. We discuss how such unconventional properties arising from quantum interference can provide a route to enhancing the sensing of analytes and facilitate broadband spectroscopy applications in integrated photonic platforms.

Published

2022

28. Fundamental resolution limit of quantum imaging with undetected photons

Author

Vega, Andres, Santos, Elkin A., Fuenzalida, Jorge, Basset, Marta Gilaberte, Pertsch, Thomas, Grafe, Markus, Saravi, Sina, and Setzpfandt, Frank

Subjects

Quantum Physics

Abstract

Quantum imaging with undetected photons relies on the principle of induced coherence without induced emission and uses two sources of photon-pairs with a signal- and an idler photon. Each pair shares strong quantum correlations in both position and momentum, which allows to image an object illuminated with idler photons by just measuring signal photons that never interact with the object. In this work, we theoretically investigate the transverse resolution of this non-local imaging scheme through a general formalism that treats propagating photons beyond the commonly used paraxial approximation. We hereby prove that the resolution of quantum imaging with undetected photons is fundamentally diffraction limited to the longer wavelength of the signal and idler pairs. Moreover, we conclude that this result is also valid for other non-local two-photon imaging schemes.

Published

2022

29. Group index matched frequency conversion in lithium niobate on insulator waveguides

Author

Kumar, Pawan, Younesi, Mohammadreza, Saravi, Sina, Setzpfandt, Frank, and Pertsch, Thomas

Subjects

Physics - Optics, Quantum Physics

Abstract

Sources of spectrally engineered photonic states are a key resource in several quantum technologies. Of particular importance are the so-called factorizable biphoton states which possess no spectral entanglement and hence, are ideal for heralded generation of high-purity single photons. An essential prerequisite for generating these states through nonlinear frequency conversion is the control over the group indices of the photonic modes of the source. Here, we show that thin-film lithium niobate on insulator (LNOI) is an excellent platform for this purpose. We design and fabricate periodically poled ridge waveguides in LNOI to demonstrate group index engineering of its guided photonic modes and harness this control to experimentally realize on-chip group index matched type-II sum-frequency generation (SFG) and photon-pair creation through spontaneous parametric down-conversion (SPDC). Also, we numerically study the role of the top cladding layer in tuning the dispersion properties of the ridge waveguide structures and reveal a distinctive difference between the air and silica-clad designs which are currently among the two most common device cladding configurations in LNOI. We expect that these results will be relevant for various classical and quantum applications where dispersion control is crucial in tailoring the nonlinear response of the LNOI-based devices.

Published

2022

30. Material-specific high-resolution table-top extreme ultraviolet microscopy

Author

Eschen, Wilhelm, Loetgering, Lars, Schuster, Vittoria, Klas, Robert, Kirsche, Alexander, Berthold, Lutz, Steinert, Michael, Pertsch, Thomas, Gross, Herbert, Krause, Michael, Limpert, Jens, and Rothhardt, Jan

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Microscopy with extreme ultraviolet (EUV) radiation holds promise for high-resolution imaging with excellent material contrast, due to the short wavelength and numerous element-specific absorption edges available in this spectral range. At the same time, EUV radiation has significantly larger penetration depths than electrons. It thus enables a nano-scale view into complex three-dimensional structures that are important for material science, semiconductor metrology, and next-generation nano-devices. Here, we present high-resolution and material-specific microscopy at 13.5 nm wavelength. We combine a highly stable, high photon-flux, table-top EUV source with an interferometrically stabilized ptychography setup. By utilizing structured EUV illumination, we overcome the limitations of conventional EUV focusing optics and demonstrate high-resolution microscopy at a half-pitch lateral resolution of 16 nm. Moreover, we propose mixed-state orthogonal probe relaxation ptychography, enabling robust phase-contrast imaging over wide fields of view and long acquisition times. In this way, the complex transmission of an integrated circuit is precisely reconstructed, allowing for the classification of the material composition of mesoscopic semiconductor systems.

Published

2021

31. Mid-Infrared Photon-Pair Generation in AgGaS$_2$

Author

Kumar, Mohit, Kumar, Pawan, Vega, Andres, Weissflog, Maximilian A., Pertsch, Thomas, and Setzpfandt, Frank

Subjects

Physics - Optics

Abstract

We demonstrate non-degenerate photon-pair generation by spontaneous parametric down conversion in a silver gallium sulfide AgGaS$_2$ crystal. By tuning the pump wavelength, we achieve phase matching over a large spectral range. This allows to generate idler photons in the mid-infrared spectral range above 6 $\mu m$ wavelength with corresponding signal photons in the visible. Also, we show photon pair generation with broad spectral bandwidth. These results are a valuable step towards the development of quantum imaging and sensing techniques in the mid-infrared.

Published

2021

32. In-fiber second-harmonic generation with embedded two-dimensional materials

Author

Ngo, Gia Quyet, Najafidehaghani, Emad, Gan, Ziyang, Khazaee, Sara, George, Antony, Schartner, Erik P., Ebendorff-Heidepriem, Heike, Pertsch, Thomas, Tuniz, Alessandro, Schmidt, Markus A., Peschel, Ulf, Turchanin, Andrey, and Eilenberger, Falk

Subjects

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

Abstract

Silica-based optical fibers are a workhorse of nonlinear optics. They have been used to demonstrate nonlinear phenomena such as solitons and self-phase modulation. Since the introduction of the photonic crystal fiber, they have found many exciting applications, such as supercontinuum white light sources and third-harmonic generation, among others. They stand out by their low loss, large interaction length, and the ability to engineer its dispersive properties, which compensate for the small chi(3) nonlinear coefficient. However, they have one fundamental limitation: due to the amorphous nature of silica, they do not exhibit second-order nonlinearity, except for minor contributions from surfaces. Here, we demonstrate significant second-harmonic generation in functionalized optical fibers with a monolayer of highly nonlinear MoS2 deposited on the fiber guiding core. The demonstration is carried out in a 3.5 mm short piece of exposed core fiber, which was functionalized in a scalable process CVD-based process, without a manual transfer step. This approach is scalable and can be generalized to other transition metal dichalcogenides and other waveguide systems. We achieve an enhancement of more than 1000x over a reference sample of equal length. Our simple proof-of-principle demonstration does not rely on either phase matching to fundamental modes, or ordered growth of monolayer crystals, suggesting that pathways for further improvement are within reach. Our results do not just demonstrate a new path towards efficient in-fiber SHG-sources, instead, they establish a platform with a new route to chi(2)-based nonlinear fiber optics, optoelectronics, and photonics platforms, integrated optical architectures, and active fiber networks., Comment: 22 pages, 11 figures

Published

2021

33. Metasurface-Assisted Quantum Ghost Discrimination of Polarization Objects

Author

Vega, Andres, Pertsch, Thomas, Setzpfandt, Frank, and Sukhorukov, Andrey A.

Subjects

Quantum Physics, Physics - Optics

Abstract

We develop a concept of metasurface-assisted ghost imaging for non-local discrimination between a set of polarization objects. The specially designed metasurfaces are incorporated in the imaging system to perform parallel state transformations in general elliptical bases of quantum-entangled or classically-correlated photons. Then, only four or fewer correlation measurements between multiple metasurface outputs and a simple polarization-insensitive bucket detector after the object can allow for the identification of fully or partially transparent polarization elements and their arbitrary orientation angles. We rigorously establish that entangled photon states offer a fundamental advantage compared to classical correlations for a broad class of objects. The approach can find applications for real-time and low-light imaging across diverse spectral regions in dynamic environments.

Published

2021

34. Spontaneous Parametric Down-Conversion from Resonant Metasurfaces

Author

Santiago-Cruz, Tomás, Fedotova, Anna, Sultanov, Vitaliy, Weissflog, Maximilian A., Arslan, Dennis, Younesi, Mohammadreza, Pertsch, Thomas, Staude, Isabelle, Setzpfandt, Frank, and Chekhova, Maria V.

Subjects

Physics - Optics, Quantum Physics

Abstract

All-dielectric optical metasurfaces are a workhorse in nano-optics due to both their ability to manipulate light in different degrees of freedom and their excellent performance at light frequency conversion. Here, we demonstrate first-time generation of photon pairs via spontaneous parametric-down conversion in lithium niobate quantum optical metasurfaces with electric and magnetic Mie-like resonances at various wavelengths. By engineering the quantum optical metasurface, we tailor the photon-pair spectrum in a controlled way. Within a narrow bandwidth around the resonance, the rate of pair production is enhanced up to two orders of magnitude compared to an unpatterned film of the same thickness and material. These results enable flat-optics sources of entangled photons -- a new promising platform for quantum optics experiments., Comment: 20 pages, 4 figures

Published

2021

35. A DIY Approach Towards Remote Labs in Photonics Education

Author

Kretzschmar, Johannes, Henkel, Clara, Domke, Jari, Sojka, Falko, Helgert, Christian, Pertsch, Thomas, Kacprzyk, Janusz, Series Editor, Gomide, Fernando, Advisory Editor, Kaynak, Okyay, Advisory Editor, Liu, Derong, Advisory Editor, Pedrycz, Witold, Advisory Editor, Polycarpou, Marios M., Advisory Editor, Rudas, Imre J., Advisory Editor, Wang, Jun, Advisory Editor, Auer, Michael E., editor, Langmann, Reinhard, editor, and Tsiatsos, Thrasyvoulos, editor

Published

2023

36. Spectral mapping of polarization-correlated photon-pair sources using quantum-classical correspondence

Author

Chung, Hung-Pin, Kumar, Pawan, Wang, Kai, Bernard, Olivier, Shirpurkar, Chinmay, Su, Wen-Chiuan, Pertsch, Thomas, Sukhorukov, Andrey A., Chen, Yen-Hung, and Setzpfandt, Frank

Subjects

Quantum Physics, Physics - Optics

Abstract

Direct spectral characterization of a quantum photon-pair source usually involves cumbersome, costly, and time-consuming detection issues. In this study, we experimentally characterize the spectral properties of a type-II phase-matched spontaneous parametric down-conversion (SPDC) source based on a titanium-diffused periodically poled lithium niobate (Ti:PPLN) waveguide. The characterization of the spectral information of the generated cross-polarized photon pairs is of importance for the use of such sources in applications including quantum information and communication. We demonstrate that the joint spectral intensity of the cross-polarized photon-pair source can be fully reconstructed using the quantum-classical correspondence through classical sum-frequency generation (SFG) measurements. This technique, which uses a much less complex detection system for visible light, opens the possibility of fast monitoring and control of the quantum state of (polarization-correlated) photon-pair sources to facilitate the realization of a stable and high-usability quantum source.

Published

2020

37. Broadband holography-assisted coherent imaging -- towards attosecond imaging at the nanoscale

Author

Eschen, Wilhelm, Wang, Sici, Liu, Chang, Steinert, Michael, Yulin, Sergiy, Meissner, Heide, Bussmann, Michael, Pertsch, Thomas, Limpert, Jens, and Rothhardt, Jan

Subjects

Physics - Optics, Electrical Engineering and Systems Science - Image and Video Processing

Abstract

In recent years nanoscale coherent imaging has emerged as an indispensable imaging modality allowing to surpass the resolution limit given by classical imaging optics. At the same time, attosecond science has experienced enormous progress and has revealed the ultrafast dynamics in atoms, molecules, and complex materials. Combining attosecond temporal resolution of pump-probe experiments with nanometer spatial resolution would allow studying ultrafast dynamics on the smallest spatio-temporal scales but has not been demonstrated yet. Unfortunately, the large bandwidth of attosecond pulses usually hinders high-resolution coherent imaging. Here we present a robust holography-enhanced coherent imaging method, which allows combining high quality and high spatial resolution coherent imaging with a large spectral bandwidth. By implementing our method at a high harmonic source we demonstrate, for the first time, a spatial resolution of 34 nm (2.5 {\lambda}) in combination with a spectral bandwidth supporting a Fourier limited pulse duration of only 380 as. The method is single-shot capable, additionally retrieves the spectrum from the measured diffraction pattern, and is thus immune against shot-to-shot fluctuations. This paves the way for an ultrafast view on nanoscale dynamics e.g. ultrafast charge transfer or ultrafast spin currents being relevant for Petahertz electronics and future data storage.

Published

2020

38. A fully automated dual-tip scanning near-field optical microscope for localized optical excitation and detection in the visible and near-infrared

Author

Abbasirad, Najmeh, Berzins, Jonas, Kollin, Kenneth, Saravi, Sina, Janunts, Norik, Setzpfandt, Frank, and Pertsch, Thomas

Subjects

Physics - Instrumentation and Detectors, Physics - Optics

Abstract

Near-field optical microscopes with two independent tips for simultaneous excitation and detection can be essential tools for studying localized optical phenomena on the subwavelength scale. Here, we report on the implementation of a fully automated and robust dual-tip scanning near-field optical microscope (SNOM), in which the excitation tip is stationary, while the detection tip automatically scans the surrounding area. To monitor and control the distance between the two probes, mechanical interactions due to shear forces are used. We experimentally investigate suitable scan parameters and find that the automated dual-tip SNOM can operate stably for a wide range of parameters. To demonstrate the potential of the automated dual-tip SNOM, we characterize the propagation of surface plasmon polaritons on a gold film for visible and near-infrared wavelengths. The good agreement of the measurements with numerical simulations verifies the capability of the dual-tip SNOM for the near-field characterization of localized optical phenomena.

Published

2020

39. Scalable functionalization of optical fibers using atomically thin semiconductors

Author

Ngo, Gia Quyet, George, Antony, Schock, Robin Tristan Klaus, Tuniz, Alessandro, Najafidehaghani, Emad, Gan, Ziyang, Geib, Nils C., Bucher, Tobias, Knopf, Heiko, Neumann, Christof, Lühder, Tilman, Warren-Smith, Stephen, Ebendorff-Heidepriem, Heike, Pertsch, Thomas, Schmidt, Markus A., Turchanin, Andrey, and Eilenberger, Falk

Subjects

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

Abstract

Atomically thin transition metal dichalcogenides are highly promising for integrated optoelectronic and photonic systems due to their exciton-driven linear and nonlinear interaction with light. Integrating them into optical fibers yields novel opportunities in optical communication, remote sensing, and all-fiber optoelectronics. However, scalable and reproducible deposition of high quality monolayers on optical fibers is a challenge. Here, we report the chemical vapor deposition of monolayer MoS2 and WS2 crystals on the core of microstructured exposed core optical fibers and their interaction with the fibers' guided modes. We demonstrate two distinct application possibilities of 2D-functionalized waveguides to exemplify their potential. First, we simultaneously excite and collect excitonic 2D material photoluminescence with the fiber modes, opening a novel route to remote sensing. Then we show that third harmonic generation is modified by the highly localized nonlinear polarization of the monolayers, yielding a new avenue to tailor nonlinear optical processes in fibers. We anticipate that our results may lead to significant advances in optical fiber based technologies.

Published

2020

40. Discrete dispersion scan setup for measuring few-cycle laser pulses in the mid-infrared

Author

Geib, Nils C., Hollinger, Richard, Haddad, Elissa, Herrmann, Paul, Légaré, François, Pertsch, Thomas, Spielmann, Christian, Zürch, Michael, and Eilenberger, Falk

Subjects

Physics - Optics

Abstract

In this work, we demonstrate a discrete dispersion scan scheme using a low number of flat windows to vary the dispersion of laser pulses in discrete steps. Monte Carlo simulations indicate that the pulse duration can be retrieved accurately with less than 10 dispersion steps, which we verify experimentally by measuring few-cycle pulses and material dispersion curves at 3 and 10 micrometer wavelength. This minimal measuring scheme using only five optical components without the need for high-precision positioners and interferometric alignment can be readily implemented in many wavelength ranges and situations., Comment: 4 pages, 5 figures

Published

2020

41. Color filter arrays based on dielectric metasurface elements

Author

Berzins, Jonas, Silvestri, Fabrizio, Gerini, Giampiero, Setzpfandt, Frank, Pertsch, Thomas, and Bäumer, Stefan M. B.

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Digital imaging has been steadily improving over the past decades and we are moving towards a wide use of multi- and hyperspectral cameras. A key component of such imaging systems are color filter arrays, which define the spectrum of light detected by each camera pixel. Hence, it is essential to develop a variable, robust and scalable way for controlling the transmission of light. Nanostructured surfaces, also known as metasurfaces, offer a promising solution as their transmission spectra can be controlled by shaping the wavelength-dependent scattering properties of their constituting elements. Here we present, metasurfaces based on silicon nanodisks, which provide filter functions with amplitudes reaching 70-90% of transmission, and well suitable for RGB and CMY color filter arrays, the initial stage towards the further development of hyperspectral filters. We suggest and discuss possible ways to expand the color gamut and improve the color values of such optical filters.

Published

2020

42. Direct and High-Throughput Fabrication of Mie-Resonant Metasurfaces via Single-Pulse Laser Interference

Author

Berzinš, Jonas, Indrišiūnas, Simonas, van Erve, Koen, Nagarajan, Arvind, Fasold, Stefan, Steinert, Michael, Gerini, Giampiero, Gečys, Paulius, Pertsch, Thomas, Bäumer, Stefan M. B., and Setzpfandt, Frank

Subjects

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

Abstract

High-index dielectric metasurfaces featuring Mie-type electric and magnetic resonances have been of a great interest in a variety of applications such as imaging, sensing, photovoltaics and others, which led to the necessity of an efficient large-scale fabrication technique. To address this, here we demonstrate the use of single-pulse laser interference for direct patterning of an amorphous silicon film into an array of Mie resonators. The proposed technique is based on laser-interference-induced dewetting. A precise control of the laser pulse energy enables the fabrication of ordered dielectric metasurfaces in areas spanning tens of micrometers and consisting of thousands of hemispherical nanoparticles with a single laser shot. The fabricated nanoparticles exhibit a wavelength-dependent optical response with a strong electric dipole signature. Variation of the pre-deposited silicon film thickness allows tailoring of the resonances in the targeted visible and infrared spectral ranges. Such direct and high-throughput fabrication paves the way towards a simple realization of spatially invariant metasurface-based devices.

Published

2020

43. Visualizing the ultra-structure of microorganisms using table-top extreme ultraviolet imaging

Author

Liu, Chang, Eschen, Wilhelm, Loetgering, Lars, Penagos Molina, Daniel S., Klas, Robert, Iliou, Alexander, Steinert, Michael, Herkersdorf, Sebastian, Kirsche, Alexander, Pertsch, Thomas, Hillmann, Falk, Limpert, Jens, and Rothhardt, Jan

Published

2023

44. Equivalence of reflection paths of light and Feynman paths in stacked metasurfaces

Author

Sperrhake, Jan, Falkner, Matthias, Fasold, Stefan, Kaiser, Thomas, and Pertsch, Thomas

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

We show the existence of virtual polarization states during the interaction of modes in metasurface stacks. In support of our findings we experimentally realize a metasurface stack, consisting of an isotropic layer of nano-patches and an anisotropic layer of nano-wires. Utilizing an analogy to the interaction of electrons at junctions in mesoscopic electron transport via Feynman paths, we present a semi-analytical description of the modal interaction inside this stack. We then derive a series of all possible reflection paths light can take inside the metasurface stack., Comment: 7 pages, 5 figures

Published

2019

45. Laser-Induced Spatially-Selective Tailoring of High-Index Dielectric Metasurfaces

Author

Berzinš, Jonas, Indrišiūnas, Simonas, Fasold, Stefan, Steinert, Michael, Žukovskaja, Olga, Cialla-May, Dana, Gečys, Paulius, Bäumer, Stefan M. B., Pertsch, Thomas, and Setzpfandt, Frank

Subjects

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

Abstract

Optically resonant high-index dielectric metasurfaces featuring Mie-type electric and magnetic resonances are usually fabricated by means of planar technologies, which limit the degrees of freedom in tunability and scalability of the fabricated systems. Therefore, we propose a complimentary post-processing technique based on ultrashort ($\leq$ 10 ps) laser pulses. The process involves thermal effects: crystallization and reshaping, while the heat is localized by a high-precision positioning of the focused laser beam. Moreover, for the first time, the resonant behavior of dielectric metasurface elements is exploited to engineer a specific absorption profile, which leads to a spatially-selective heating and a customized modification. Such technique has a potential to reduce the complexity in the fabrication of non-uniform metasurface-based optical elements. Two distinct cases, a spatial pixelation of a large-scale metasurface and a height modification of metasurface elements, are explicitly demonstrated.

Published

2019

46. In-fibre second-harmonic generation with embedded two-dimensional materials

Author

Ngo, Gia Quyet, Najafidehaghani, Emad, Gan, Ziyang, Khazaee, Sara, Siems, Malte Per, George, Antony, Schartner, Erik P., Nolte, Stefan, Ebendorff-Heidepriem, Heike, Pertsch, Thomas, Tuniz, Alessandro, Schmidt, Markus A., Peschel, Ulf, Turchanin, Andrey, and Eilenberger, Falk

Published

2022

47. Sub-micrometer Nanostructure-based RGB Filters for CMOS Image Sensors

Author

Berzinš, Jonas, Fasold, Stefan, Pertsch, Thomas, Bäumer, Stefan M. B., and Setzpfandt, Frank

Subjects

Physics - Optics

Abstract

Digital color imaging relies on spectral filters on top of a pixelated sensor, such as a CMOS image sensor. An important parameter of imaging devices is their resolution, which depends on the size of the pixels. For many applications, a high resolution is desirable, consequently requiring small spectral filters. Dielectric nanostructures, due to their resonant behavior and its tunability, offer the possibility to be assembled into flexible and miniature spectral filters, which could potentially replace conventional pigmented and dye-based color filters. In this paper, we demonstrate the generation of transmissive structural colors based on uniform-height amorphous silicon nanostructures. We optimize the structures for the primary RGB colors and report the construction of sub-micrometer RGB filter arrays for a pixel size down to 0.5 {\mu}m.

Published

2018

48. All-dielectric resonant meta-optics goes active

Author

Staude, Isabelle, Pertsch, Thomas, and Kivshar, Yuri

Subjects

Physics - Optics

Abstract

All-dielectric resonant nanophotonics is a rapidly developing research field driven by its exceptional application potential for low-loss nanoscale metadevices. The tight confinement of the local electromagnetic fields and interferences in resonant photonic nanostructures can boost many optical effects, thus offering novel opportunities for the subwavelength control of light-matter-interactions. Active, light-emitting nanoscale structures are of particular interest, as they offer unique opportunities for novel types of light sources and nanolasers. Here, we review the latest advances in this recently emerged and rapidly growing field of active dielectric resonant nanophotonics enabled by dipolar and multipolar Mie-type resonances. More specifically, we discuss how to employ dielectric nanostructures for the resonant control of emission from quantum dots, two-dimensional transition metal dichalcogenides, and halide perovskites. We also foresee various future research directions and applications of active all-dielectric resonant nanostructures including but not limited to lasing in topologically robust systems, light-matter interactions beyond the electric dipole limit, light-emitting surfaces, and tunable active metadevices., Comment: Invited Perspective for ACS Photonics

Published

2018

49. Using effective medium theories to design tailored nanocomposite materials for optical systems

Author

Werdehausen, Daniel, Staude, Isabelle, Burger, Sven, Petschulat, Jörg, Scharf, Toralf, Pertsch, Thomas, and Decker, Manuel

Subjects

Physics - Optics

Abstract

Modern optical systems are subject to very restrictive performance, size and cost requirements. Especially in portable systems size often is the most important factor, which necessitates elaborate designs to achieve the desired specifications. However, current designs already operate very close to the physical limits and further progress is difficult to achieve by changing only the complexity of the design. Another way of improving the performance is to tailor the optical properties of materials specifically to the application at hand. A class of novel, customizable materials that enables the tailoring of the optical properties, and promises to overcome many of the intrinsic disadvantages of polymers, are nanocomposites. However, despite considerable past research efforts, these types of materials are largely underutilized in optical systems. To shed light into this issue we, in this paper, discuss how nanocomposites can be modeled using effective medium theories. In the second part, we then investigate the fundamental requirements that have to be fulfilled to make nanocomposites suitable for optical applications, and show that it is indeed possible to fabricate such a material using existing methods. Furthermore, we show how nanocomposites can be used to tailor the refractive index and dispersion properties towards specific applications., Comment: This is a draft manuscript of a paper published in Proc. SPIE (Proceedings Volume 10745, Current Developments in Lens Design and Optical Engineering XIX, Event: SPIE Optical Engineering + Applications, 2018)

Published

2018

50. Common pulse retrieval algorithm: a fast and universal method to retrieve ultrashort pulses

Author

Geib, Nils C., Zilk, Matthias, Pertsch, Thomas, and Eilenberger, Falk

Subjects

Physics - Instrumentation and Detectors, Physics - Optics

Abstract

We present a common pulse retrieval algorithm (COPRA) that can be used for a broad category of ultrashort laser pulse measurement schemes including frequency-resolved optical gating (FROG), interferometric FROG, dispersion scan, time domain ptychography, and pulse shaper assisted techniques such as multiphoton intrapulse interference phase scan (MIIPS). We demonstrate its properties in comprehensive numerical tests and show that it is fast, reliable and accurate in the presence of Gaussian noise. For FROG it outperforms retrieval algorithms based on generalized projections and ptychography. Furthermore, we discuss the pulse retrieval problem as a nonlinear least-squares problem and demonstrate the importance of obtaining a least-squares solution for noisy data. These results improve and extend the possibilities of numerical pulse retrieval. COPRA is faster and provides more accurate results in comparison to existing retrieval algorithms. Furthermore, it enables full pulse retrieval from measurements for which no retrieval algorithm was known before, e.g., MIIPS measurements.

Published

2018