Integrated optics prototype beam combiner for long baseline interferometry in the <i>L </i>and <i>M </i>bands

Tepper, Jan; Labadie, Lucas; Diener, Romina; Minardi, Stefano; Pott, Jörg-Uwe; Thomson, Robert R.; Nolte, Stefan

doi:10.1051/0004-6361/201630138

Cited by 39 publications

(24 citation statements)

References 32 publications

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“…A periodic 3D array of WGs is also an excellent platform for light coupling and performing interferometry of the light that comes from telescopes. 157,161,166 Though laboratory testing and on-sky testing have indicated that the integrated WGs written by fs lasers hold great potential in astrophotonics, there are still some issues hindering their wide application. For example, chalcogenide and fluoride glasses are fascinating alternatives for mid-infrared optic detecting in the range from 2 to 5 μm, which are in high demand for high angular resolution astrophotonics.…”

Section: Astrophotonicsmentioning

confidence: 99%

Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices

et al. 2021

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Integrated photonics is attracting considerable attention and has found many applications in both classical and quantum optics, fulfilling the requirements for the ever-growing complexity in modern optical experiments and big data communication. Femtosecond (fs) laser direct writing (FLDW) is an acknowledged technique for producing waveguides (WGs) in transparent glass that have been used to construct complex integrated photonic devices. FLDW possesses unique features, such as three-dimensional fabrication geometry, rapid prototyping, and single step fabrication, which are important for integrated communication devices and quantum photonic and astrophotonic technologies. To fully take advantage of FLDW, considerable efforts have been made to produce WGs over a large depth with low propagation loss, coupling loss, bend loss, and highly symmetrical mode field. We summarize the improved techniques as well as the mechanisms for writing high-performance WGs with controllable morphology of cross-section, highly symmetrical mode field, low loss, and high processing uniformity and efficiency, and discuss the recent progress of WGs in photonic integrated devices for communication, topological physics, quantum information processing, and astrophotonics. Prospective challenges and future research directions in this field are also pointed out.

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Section: Astrophotonicsmentioning

confidence: 99%

Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices

et al. 2021

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“…These are potential solutions to detect exoplanets, and miniaturized devices for on-sky detection were proposed. [150,[163][164][165] Applications in astrophotonics were reviewed in several occasions ( [140,161] and the reference therein), and will only briefly be recalled here. It is interesting to point out that commercial ultrafast laser solutions are already proposed for laser-fabricated integrated devices.…”

Section: Photonics Applicationsmentioning

confidence: 99%

Volume photoinscription of glasses: three-dimensional micro- and nanostructuring with ultrashort laser pulses

Stoian

2020

Appl. Phys. A

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Ultrafast laser photoinscription of optical materials has seen a strong development in the recent years for a range of applications in integrated photonics. Fueled by its capability to confine energy in micro-domains of arbitrary geometries, it forecasts extensive potential in optical design. The process can locally modify the material structure and the electronic properties, changing in turn the refractive index. It thus lays down a powerful concept for three-dimensional modifications with the potential to design integrated optical functions. Using fused silica as model glass, this report discusses the physical mechanisms of photoinscription, outlining the possibility of refractive index engineering. We will review basic mechanisms of light propagation, excitation of matter, and energy relaxation concurring to material structural and photo-physical modification. A dynamic perspective will be given, indicating relevant times for relaxing different forms of energy (electronic, thermal, etc.). The possibility to structure beyond diffraction limit will be explored, as well as the subsequent optical response of hybrid micro-nano structures. Different irradiation geometries for photoinscription will be presented, pinpointing their potential to generate optical and photonic systems in 3D. Spatio-temporal pulse engineering can optimize the material response towards the achievement of accurate positive and negative index changes. An optimality concept can thus be defined for index design. A particular potential derives from the utilisation of non-diffractive beams with engineered dispersion. Finally we indicate a range of application domains, from telecom to optofluidics and astrophotonics, outlining the potential of volume micro and nanoprocessing.

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“…The spectral beam combiners work on the principle of using emitters with the use of non-overlapping emission spectra. Then every single beam is fed to the combiner, which is a wavelength sensitive beam combiner and uses components like, diffraction gratings, volume Bragg grating, dichroic mirrors or prisms [6].…”

Section: Spectral Beam Combinersmentioning

confidence: 99%

Simulation and Analysis of Telescopic Photonic Beam Combiner for Stellar Interferometry in Labview

2019

IJITEE

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The optical methods are the sensitive and subtle techniques of conducting optical investigations without any physical contact. They are both accurate and fast at the same time which provides an ease of having multiple observations. The need of optical interferometry has been increased at a very quick pace due to its high range of applications, from surface testing to locating of extra-solar planets in the universe. Optical Interferometry is a process or technique of combining light from various telescopes for calculating the angular resolution. The technique of optical interferometry helps astronomers for achieving a high angular resolution, that is not possible with the conventional telescopes. Optical approaches are the best approaches for non-contact evaluations, and these are accurate and fast. Due to optical nature of the interferometry, this process is used in various fields, and today it has become one of the important areas of research. Integrated Optics (IO) beam combiners are an efficient and compact technology to combine light interferometrically collected by multiple telescopes. IO beam combiner is based on the modal filtering properties of waveguides or fibers, and it improves thermo-mechanical stability, because of the characteristic rigidity of IO component substrate. Other advantages of this technology are miniaturization and non-existence of alignment needs. Several IO beam combiners are being proposed and tested nowadays. The purpose of this paper is to investigate different techniques used to develop interferometric instrument from previous researches and to simulate the technique suggested by Ermann in Labview.

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Integrated optics prototype beam combiner for long baseline interferometry in the L and M bands

Cited by 39 publications

References 32 publications

Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices

Photonic circuits written by femtosecond laser in glass: improved fabrication and recent progress in photonic devices

Volume photoinscription of glasses: three-dimensional micro- and nanostructuring with ultrashort laser pulses

Simulation and Analysis of Telescopic Photonic Beam Combiner for Stellar Interferometry in Labview

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