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27 results on '"Boller K"'

1. Using hybrid integrated InP-Si3N4 diode lasers for the generation of sub-GHz repetition rate frequency combs

Author

Memon, A., van Rees, A., Mak, J., Fan, Y., van der Slot, P.J.M., Bastiaens, H.M.J., Boller, K.-J., Garcia-Blanco, Sonia M., Cheben, Pavel, Laser Physics & Nonlinear Optics, and MESA+ Institute

Subjects
Low Repetition Rate, Hybrid Mode-locking, Mode-locked Lasers, Extended Cavity Diode Lasers, Hybrid Integrated Diode Lasers, Fourier Domain Mode-Locking, Passive Mode-Locking, Optical Frequency Combs
Abstract

Optical frequency combs based on broadband-gain bulk lasers, due to the low intrinsic linewidth and sub-GHz repetition rates, have gained tremendous interest for applications such as high-resolution spectroscopy, dual-comb spectroscopy or LIDAR. However, susceptibility to mechanical and acoustic perturbations, the complexity of optical pumping and the larger physical size of these lasers has motivated research toward chip-based integrated extended cavity diode lasers with low-loss Si3N4 waveguide feedback circuits for low repetition rates. In diode lasers, mode-locking via saturable absorbers is generally used for generating frequency combs, however, the short upper-state carrier lifetime results in repetition rates of at least a few GHz. Here, we demonstrate absorber-free, passive mode-locking as well as hybrid mode-locking at sub-GHz repetition rates using a long Si3N4 feedback circuit with three highly frequency-selective microring resonators for extending the cavity roundtrip length to more than 0.6 m. This enables frequency-domain mode-locking in the form of a continuous wave, with a line spacing of around 500 MHz. Hybrid mode-locking, in addition to passive mode-locking, is demonstrated by adding a weak AC drive current with a frequency close to 500 MHz. This stabilizes the repetition rate and reduces the Gaussian component of the laser’s RF linewidth attaining a negligible Lorentzian component. Our numerical simulations predict that further lowering of the repetition rate and line spacings might be achievable with further cavity length extension.

Published
2023
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2. Hybrid integrated near UV lasers using the deep-UV Al2O3 platform

Author

Franken, C. A. A., Hendriks, W. A. P. M., Winkler, L. V., Dijkstra, M., Nascimento Jr, A. R. do, van Rees, A., Mardani, M. R. S., Dekker, R., van Kerkhof, J., van der Slot, P. J. M., García-Blanco, S. M., and Boller, K. -J.

Subjects
FOS: Physical sciences, Physics - Applied Physics, Applied Physics (physics.app-ph), Physics - Optics, Optics (physics.optics)
Abstract

Hybrid integrated diode lasers have so far been realized using silicon, polymer, and silicon nitride (Si3N4) waveguide platforms for extending on-chip tunable light engines from the infrared throughout the visible range. Here we demonstrate the first hybrid integrated laser using the aluminum oxide (Al2O3) deep-UV capable waveguide platform. By permanently coupling low-loss Al2O3 frequency-tunable Vernier feedback circuits with GaN double-pass amplifiers in a hermetically sealed housing, we demonstrate the first extended cavity diode laser (ECDL) in the near UV. The laser shows a maximum fiber-coupled output power of 0.74 mW, corresponding to about 3.5 mW on chip, and tunes more than 4.4 nm in wavelength from 408.1 nm to 403.7 nm. Integrating stable, single-mode and tunable lasers into a deep-UV platform opens a new path for chip-integrated photonic applications., Comment: 14 pages, 3 figures

Published
2023
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5. Electromagnetic radiation from a laser wakefield accelerator

Author

Khachatryan, A. G., van Goor, F. A., and Boller, K. -J.

Subjects
Accelerator Physics (physics.acc-ph), Plasma Physics (physics.plasm-ph), Physics::Accelerator Physics, FOS: Physical sciences, Physics - Accelerator Physics, Physics - Plasma Physics
Abstract

Coherent and incoherent electromagnetic radiation emitted from a laser wakefield accelerator is calculated based on Lienard-Wiechert potentials. It is found that at wavelengths longer than the bunch length, the radiation is coherent. The coherent radiation, which typically lies in the infrared range, shows features that reveal details of the acceleration process and properties of the electron bunch, such as its duration, charge, energy, and offset with respect to the wakefield axis. The incoherent range of the spectrum, which extends to the X-ray frequency range, consists of rather broad peaks, which are caused by the acceleration., Comment: 14 pages, incl. 6 figures, submitted for publication

Published
2008
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20. High harmonic source for seeding of FERMI@Elettra

Author

Goh, S. J., Slot, P. J. M., Bert Bastiaens, Biedron, S. G., Danailov, M. B., Milton, S. V., Herek, J., Boller, K. J., Laser Physics & Nonlinear Optics, and Optical Sciences

Abstract

FERMI@Elettra is a free electron laser user facility that will produce high-brightness, ultra-short pulses with broad wavelength coverage for a wide range of user experiments. Currently, FERMI uses the HGHG technique to improve both the longitudinal and spectral coherence and the stability of the output of the laser. Using a High Harmonic (HH) source to drive the HGHG process will allow FERMI to reach shorter wavelengths with a single stage. It also will provide a comparison between HH and HGHG seeding methods. For the HH source, we will use neutral atoms in a hollow waveguide in combination with pulse shaping of the drive laser pulse to provide wavelength tuning as well as selective enhancement of the harmonic orders. In this paper, we the discuss the scaling of HH generation to several hundreds of nanoJoule pulse energy at a specific harmonic (several tens of MW peak power) and present the HH source under construction at the university of Twente.

22. Improved resolution for soft-x-ray monochromatization using lamellar multilayer gratings

Author

van der Meer, R., Krishnan, B., Kozhevnikov, I.V., de Boer, M.J., Vratzov, B., Bastiaens, H.M.J., Huskens, J., van der Wiel, W.G., Hegeman, P.E., Brons, G.C.S., Boller, K.-J., Bijkerk, F., Morawe, Christian, Khounsary, Ali M., Goto, Shunji, Laser Physics & Nonlinear Optics, and Molecular Nanofabrication

Subjects
Diffraction, Soft-X-ray, Fabrication, Materials science, business.industry, Coupled waves, METIS-278371, Resolution (electron density), Bosch DRIE, Grating, Bragg reflectors, Synchrotron, law.invention, Optics, Beamline, law, Deep reactive-ion etching, Optoelectronics, UV-NIL, Lamellar multilayer grating, business, Lithography
Abstract

Lamellar Multilayer Gratings (LMG) offer improved resolution for soft-x-ray (SXR) monochromatization, while maintaining a high reflection efficiency in comparison to conventional multilayer mirrors (MM). We previously used a Coupled-Waves Approach (CWA) to calculate SXR diffraction by LMGs and identified a single-order regime in which the incident wave only excites a single diffraction order. We showed that in this regime the angular width of the zeroth-order diffraction peak simply scales linearly with Γ (lamel-to-period ratio) without loss of peak reflectivity. However, the number of bi-layers must then be increased by a factor of 1/Γ. Optimal LMG resolution and reflectivity is obtained in this single-order regime, requiring grating periods of only a few hundred nm, lamel widths < 100nm and lamel heights > 1μm [1]. For the fabrication of LMGs with these dimensions, we use a novel process based on UV-NanoImprint Lithography (UV-NIL) and Bosch-type Deep Reactive Ion Etching (DRIE). Successful fabrication of LMGs with periods down to 200nm, line widths of 60nm and multilayer stack heights of 1μm is demonstrated. SXR reflectivity measurements were performed on these LMGs at the PTB beamline at the BESSYII synchrotron facility. The measurements demonstrate an improvement in resolution by a factor 3,5 compared to conventional MMs. Further analysis of the SXR reflectivity measurements is currently being performed.

23. Integrated programmable waveguide circuits for classical and quantum photonic processing

Author

Caterina Taballione, Boller, K.-J., Pinkse, Pepijn, and Laser Physics & Nonlinear Optics

Subjects
Spectral signal processing, Materials science, business.industry, Integrated photonics, Photonic integrated circuit, Physics::Optics, Programmable waveguide circuits, law.invention, Resonator, chemistry.chemical_compound, Interferometry, Silicon nitride, chemistry, Interference (communication), law, Quantum information processing, Optoelectronics, Photonics, business, Waveguide, Electronic circuit
Abstract

Programmable waveguide circuits are crucial building blocks for integrated spectrometric applications and quantum photonic information processing. Amongst the dielectric material platforms in integrated photonics, silicon nitride stands out with highly attractive properties such as a large bandgap energy and a moderately high index contrast. This allows low propagation losses in a wide spectral range while simultaneously allowing a dense packing of components. The aforementioned properties, together with the inherent phase stability and phase programmability achievable in silicon nitride, enable the creation of complex photonic circuits. In this thesis we describe and demonstrate densely integrated programmable photonic circuits based on silicon nitride waveguides for wavelength metrology and quantum information processing. We concentrate on reconfigurable photonic integrated circuits based on silicon nitride waveguides with low-loss propagation, to explore interference in the spectral and temporal domain for advanced applications. We investigated two types of integrated interferometric devices featuring low loss in combination with programmability for classical and quantum photonic processing. The first is simple tunable microring resonator circuits in combination with neural network data processing for the analysis of classical light in the spectral domain as wavelength meter. The second is a complex tunable network of waveguide interferometers for controlling quantum correlations (coincidences) between single photons. Exploiting the long-term interferometric stability, low propagation loss and tight optical confinement of integrated silicon nitride waveguides, we have shown complex reconfigurable optical circuits both for classical and quantum photonic processing. For future development of integrated programmable photonic processors, various challenges need to be addressed such as compact and low-power phase shifters, a further increase of the component density and lower the propagation losses.

Published
2019
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24. Toward spatial and spectral control of waveguided high-harmonic generation

Author

S.J. Goh, Boller, K.-J., Bastiaens, H.M.J., Faculty of Science and Technology, Optical Sciences, and Laser Physics & Nonlinear Optics

Subjects
Physics, business.industry, Physics::Optics, Radiation, Laser, 01 natural sciences, 7. Clean energy, law.invention, 010309 optics, Wavelength, Optics, law, Extreme ultraviolet, 0103 physical sciences, High harmonic generation, Optoelectronics, 010306 general physics, business, Waveguide, Wavelength band, Coherence (physics)
Abstract

Generating intense radiation in the wavelength band of the extreme ultraviolet (XUV, 100 to 10 nm) remains a very challenging goal in today’s scientific research. In this thesis, we describe a unique XUV source based on high harmonic generation. We have thoroughly investigated a number of intrinsic properties of high harmonic generation in a waveguided geometry. We conclude that using waveguides allows for spatial and spectral control of high-harmonic radiation. Our studies have also shown that waveguided high harmonic generation is particularly suited for producing radiation at XUV wavelengths with excellent beam coherence and unique spectral features. Future work, focused on using higher drive laser energy and larger waveguide diameters offer the potential of achieving higher XUV output energy.

Published
2015
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25. Propagation and nonlinear scattering of ultrashort pulses : examples of modeling and applications

Author

Willem Paul Beeker, Boller, K.-J., Lee, C.J., and University of Twente

Subjects
Physics, Nonlinear system, IR-69681, Optics, business.industry, Physics::Optics, business, Nonlinear scattering
Abstract

In this thesis we have presented theoretical and experimental investigations of some fundamental properties and applications of nonlinear interaction between ultrashort optical pulses and matter.

Published
2009
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27. All optical frequency division with self-phase-locked parametric oscillators

Author

Gross, P., Boller, K.-J., and Laser Physics & Nonlinear Optics

Subjects
METIS-212164, IR-40534
Abstract

The goal of the current work is to considerably expand the range accessible for high precision metrology.A new method is investigated both theoretically and experimentally, in order to enable the measurement of unknown frequencies in a spectral range, which is currently not yet easy approachable.

Published
2003

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