Your search keyword '"Zurak, Luka"' showing total 14 results

1. Double helical plasmonic antennas

Author

Tsarapkin, Aleksei, Zurak, Luka, Maćkosz, Krzysztof, Utke, Ivo, Feichtner, Thorsten, and Höflich, Katja

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Plasmonic double helical antennas are a means to funnel circularly polarized states of light down to the nanoscale. Here, an existing design tool for single helices is extended to the case of double helices and used to design antennas that combine large chiroptical interaction strength with highly directional light emission. Full-field numerical modeling underpins the design and provides additional insight into surface charge distributions and resonance widths. The experimentally realized double helical antennas were studied regarding their polarization-dependent transmission behavior resulting in a large and broadband dissymmetry factor in the visible range. Since the polarization of light is an important tool for implementing logic functionality in photonic and quantum photonic devices, these helices are potential building blocks for future nanophotonic circuits, but also for chiral metamaterials or phase plates., Comment: 11 pages with Supporting Information, 10 figures

Published

2024

2. Direct electrical modulation of surface response in a single plasmonic nanoresonator

Author

Zurak, Luka, Wolff, Christian, Meier, Jessica, Kullock, Rene, Mortensen, N. Asger, Hecht, Bert, and Feichtner, Thorsten

Subjects

Physics - Optics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Classical electrodynamics describes the optical response of systems using bulk electronic properties and infinitesimally thin boundaries. However, due to the quantum nature of electrons, interfaces have a finite thickness. Non-classical surface effects become increasingly important as ever smaller nanoscale systems are realized and eventually dominate over volume-related phenomena. Investigating the response of surface electrons in such systems, therefore, becomes imperative. One way to gain control over non-classical interface effects and study them is through electrical gating, as the static screening charges reside exclusively at the surface. Here, we investigate the modulation of the surface response upon direct electric charging of a single plasmonic nanoresonator by measuring the resulting changes in resonance. We analyze the observed effects within the general framework of surface-response functions and provide a basic model derived from electron spill-out within the local-response approximation (LRA). Our observed change in resonance frequency is well accounted for by assuming a modulation of the in-plane surface current. Surprisingly, we also measure a change in the resonance width, where adding electrons to the surface leads to a narrowing of the plasmonic resonance, i.e., reduced losses. The description of such effects requires considering nonlocal effects and the inclusion of a possible anisotropy of the perturbed surface permittivity. Our experiment, therefore, opens a vast field of investigations on how to gain control over the surface response in plasmonic resonators and to develop ultrafast and extremely small electrically driven plasmonic modulators and metasurfaces by leveraging electrical control over non-classical surface effects., Comment: 10 pages, 4 figures, 15 pages Supplementary

Published

2023

3. Controlling field asymmetry in nanoscale gaps for second harmonic generation

Author

Meier, Jessica, Zurak, Luka, Locatelli, Andrea, Feichtner, Thorsten, Kullock, René, and Hecht, Bert

Subjects

Physics - Optics

Abstract

Plasmonic dimer antennas create strong field enhancement by squeezing light into a nanoscale gap. These optical hotspots are highly attractive for boosting nonlinear processes, such as harmonic generation, photoelectron emission, and ultrafast electron transport. Alongside large field enhancement, such phenomena often require control over the field asymmetry in the hotspot, which is challenging considering the nanometer length scales. Here, by means of strongly enhanced second harmonic generation, we demonstrate unprecedented control over the field distribution in a hotspot by systematically introducing geometrical asymmetry to the antenna gap. We use focused helium ion beam milling of mono-crystalline gold to realize asymmetric-gap dimer antennas in which an ultra-sharp tip with 3 nm apex radius faces a flat counterpart, conserving the bonding antenna mode and the concomitant field enhancement at the fundamental frequency. By decreasing the tip opening angle, we are able to systematically increase both field enhancement and asymmetry, thus enhancing second harmonic radiation to the far-field, which is nearly completely suppressed for equivalent symmetric dimer antennas. Combining these findings with second harmonic radiation patterns as well as quantitative nonlinear simulations, we further obtain remarkably detailed insights into the mechanism of second harmonic generation at the nanoscale. Our results open new opportunities for the realization of novel nonlinear nanoscale systems, where the control over local field asymmetry in combination with large field enhancement is essential to create nonreciprocal functionalities.

Published

2022

4. Tunable nano-plasmonic photodetectors

Author

Pertsch, Patrick, Kullock, René, Gabriel, Vinzenz, Zurak, Luka, Emmerling, Monika, and Hecht, Bert

Subjects

Physics - Optics, Physics - Applied Physics

Abstract

Visible and infrared photons can be detected with a broadband response via the internal photoeffect. By using plasmonic nanostructures, i.e. nanoantennas, wavelength selectivity can be introduced to such detectors through geometry-dependent resonances. Also, additional functionality, like electronic responsivity switching and polarization detection have been realized. However, previous devices consisted of large arrays of nanostructures to achieve detectable photocurrents. Here we show that this concept can be scaled down to a single antenna level, resulting in detector dimensions well below the resonance wavelength of the device. Our design consists of a single electrically-connected plasmonic nanoantenna covered with a wide-bandgap semiconductor allowing broadband photodetection in the VIS/NIR via injection of hot carriers. We demonstrate electrical switching of the color sensitivity as well as polarization detection. Our results hold promise for the realization of ultra small, highly integratable photodetectors with advanced functionality., Comment: 8 pages, 4 figures

Published

2022

5. Modulation of surface response in a single plasmonic nanoresonator.

Author

Zurak, Luka, Wolf, Christian, Meier, Jessica, Kullock, René, Mortensen, N. Asger, Hecht, Bert, and Feichtner, Thorsten

Subjects

*LIGHT scattering, *PLASMONICS, *RESONATORS, *RESONANCE, *NANOPARTICLES

Abstract

Scattering of light by plasmonic nanoparticles is classically described using bulk material properties with infinitesimally thin boundaries. However, because of the quantum nature of electrons, real interfaces have finite thickness, leading to nonclassical surface effects that influence light scattering in small particles. Electrical gating offers a promising route to control and study these effects, as static screening charges reside at the boundary. We investigate the modulation of the surface response upon direct electrical charging of single plasmonic nanoresonators. By analyzing measured changes in light scattering within the framework of surface response functions, we find the resonance shift well accounted for by modulation of the classical in-plane surface current. Unexpectedly, we also observed a change in the resonance width, indicating reduced losses for negatively charged resonators. This effect is attributed to a nonclassical out-of-plane surface response, extending beyond pure spill-out effects. Our experiments pave the way for electrically driven plasmonic modulators and metasurfaces, leveraging control over nonclassical surface effects. [ABSTRACT FROM AUTHOR]

Published

2024

6. Controlling Field Asymmetry in Nanoscale Gaps for Second Harmonic Generation

Author

Meier, Jessica, primary, Zurak, Luka, additional, Locatelli, Andrea, additional, Feichtner, Thorsten, additional, Kullock, René, additional, and Hecht, Bert, additional

Published

2023

7. Fast Electrical Modulation of Single Plasmonic Nano-Rod Resonance

Author

Zurak, Luka, primary, Meier, Jessica, additional, Kullock, Rene, additional, Hecht, Bert, additional, and Feichtner, Thorsten, additional

Published

2023

8. From Static to Dynamic Modulation of Second Harmonic Generation from Plasmonic Hotspots

Author

Meier, Jessica, primary, Zurak, Luka, additional, Locatelli, Andrea, additional, Feichtner, Thorsten, additional, Kullock, René, additional, and Hecht, Bert, additional

Published

2023

9. Tunable Nanoplasmonic Photodetectors

Author

Pertsch, Patrick, primary, Kullock, René, additional, Gabriel, Vinzenz, additional, Zurak, Luka, additional, Emmerling, Monika, additional, and Hecht, Bert, additional

Published

2022

10. Nanoscale Electrical Excitation of Distinct Modes in Plasmonic Waveguides

Author

Ochs, Maximilian, primary, Zurak, Luka, additional, Krauss, Enno, additional, Meier, Jessica, additional, Emmerling, Monika, additional, Kullock, René, additional, and Hecht, Bert, additional

Published

2021

11. Electrically-driven Plasmonics

Author

Hecht, Bert, primary, Kullock, René, additional, Ochs, Max, additional, Grimm, Philipp, additional, Zurak, Luka, additional, Pertsch, Patrick, additional, Friedrich, Daniel, additional, Meier, Jessica, additional, Schurr, Benedikt, additional, and Emmerling, Monika, additional

Published

2020

12. Testing scalar diffraction theory: Gaussian beam on a slit

Author

Zurak, Luka, primary, Labinac, Velimir, additional, Erceg, Nataša, additional, Aviani, Ivica, additional, Jusup, Marko, additional, and Karuza, Marin, additional

Published

2020

13. Eksperimentalno ispitivanje skalarne teorije ogiba

Author

Zurak, Luka and Karuza, Marin

Subjects

PRIRODNE ZNANOSTI. Fizika, scalar theory of diffraction, NATURAL SCIENCES. Physics

Abstract

In this thesis diraction by a rectangular aperture is inspected. Measured data is collected, using digital camera CMOS sensor, and compared with theoretically obtained results calculated using symbolic computation program Mathematica 11.0. Theoretical analysis done by Kirchho is based on usage of Green's function and Green's second identity in combination with scalar wave equation. With proper boundary conditions three diraction formulas were obtained - one of the goals was to inspect which of mentioned formulas provide best foresight. To provide suitable and complete theoretical results, incident wave -in this case laser beam- is modeled using Gaussian beam. Controlling incident eld four cases were inspected regarding geometry of object light is diracted by. We start with diraction by a straight edge where only variable parameter is edge-sensor distance. Controlling this parameter normal incidence diraction by a slit is inspected. In this way slit width was recalibrated. Knowing both, mentioned distance, and slit width inclined incidence diraction was examined. To justify obtained results geometric corrections had to be imported. In such way observing diraction patterns we can inspect geometry of slit edges. At last, one of the slit wings was on-axis displaced and diraction by a shifted slit was observed. Comparing experimental and theoretical results we can conclude that scalar theory provides satisfactory results compared to experimental results. However, to provide more accurate measurements more symmetric slit with smoother surface of the blades, to lower distortion of diraction patterns, is needed. Distortion is especially striking for small widths. Also, it is shown that for large inclinations at angle incidence is more accurately presented using theoretical implications for diraction by a shifted slit.

Published

2017

14. Istraživanje strukture atoma u srednjoj školi primjenom suvremene tehnologije

Author

Zurak, Luka, Barac, Marko, Špirić, Ljubomir, Erceg, Nataša, Karuza, Marin, and Aviani, Ivica

Subjects

nastava fizike, struktura atoma, kritični potencijal, Red Pitaya, QtiPlot

Abstract

U ovom radu opisan je pokus kojim se analizira struktura energijskih razina atoma nepoznatog plina unutar staklene cijevi. U pokusu se obuđuju atomi plina sudarima s elektronima malih kinetičkih energija te se analizira izmjerena struja nastala prikupljanjem spomenutih elektrona koji su izgubili kinetičku energiju uslijed neelastičnih sudara sa elektronima iz elektronskog omotača atoma. Uz pomoć jeftinog multifunkcionalnog uređaja RedPitaya mjerena je struja elektrona koji su izgubili kinetičku energiju u sudarima, odnosno posredno energetske razine u elektronskom omotaču atoma. Isti uređaj upotrijebljen je i za kalibraciju ubrzavajućeg napona. Usporedbom rezultata dobivenih eksperimentom (obrađenih računalnim programom QtiPlot) te poznatih vrijednosti, moguće je odrediti vrstu plina kojim je ispunjena staklena cijev. Iako je ovaj eksperiment u proširenom obliku namijenjen za sveučilišnu nastavu u sklopu kolegija Praktikum iz strukture tvari na Odjelu za fiziku Sveučilišta u Rijeci, moguće ga je prilagoditi za srednjoškolsku nastavu, uz primjenu različitih nastavnih metoda i oblika rada. U skladu sa srednjoškolskim nastavnim planom i programom, pokus obuhvaća koncepte iz atomske fizike, elektriciteta i mehanike. Stoga, primjerice u 4. razredu može poslužiti za dublje razumijevanje koncepata koji se tek uvode (npr. atomski spektar i energija atoma), za usustavljivanje ranije usvojenih pojmova (npr. električni potencijal, gibanje naboja u električnom polju, električna struja i napon, neelastični sudari), te za direktnu primjenu suvremene tehnologije u okvirima odgovarajućih srednjoškolskih sadržaja iz fizike.

Published

2017