J. Olszewski scite author profile

We designed, manufactured and characterized two birefringent microstructured fibers that feature a 5-fold increase in polarimetric sensitivity to hydrostatic pressure compared to the earlier reported values for microstructured fibers. We demonstrate a good agreement between the finite element simulations and the experimental values for the polarimetric sensitivity to pressure and to temperature. The sensitivity to hydrostatic pressure has a negative sign and exceeds -43 rad/MPa x m at 1.55 microm for both fibers. In combination with the very low sensitivity to temperature, this makes our fibers the candidates of choice for the development of microstructured fiber based hydrostatic pressure measurement systems.

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Plug&Play Fiber‐Coupled 73 kHz Single‐Photon Source Operating in the Telecom O‐Band

Musiał

Żołnacz

Srocka

et al. 2020

Adv Quantum Tech

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A user‐friendly, fiber‐coupled, single‐photon source operating at telecom wavelengths is a key component of photonic quantum networks providing long‐haul, ultra‐secure data exchange. To take full advantage of quantum‐mechanical data protection and to maximize the transmission rate and distance, a true quantum source providing single photons on demand is highly desirable. This great challenge is tackled by developing a ready‐to‐use semiconductor quantum‐dot‐based device that launches single photons at a wavelength of 1.3 µm directly into a single‐mode optical fiber. In the proposed approach, the quantum dot is deterministically integrated into a nanophotonic structure to ensure efficient on‐chip coupling into a fiber. The whole arrangement is integrated into a 19ʺ compatible housing to enable stand‐alone operation by cooling via a compact Stirling cryocooler. The realized source delivers single photons with a multiphoton events probability as low as 0.15 and a single‐photon emission rate of up to 73 kHz into a standard telecom single‐mode fiber.

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Experimental and theoretical investigations of birefringent holey fibers with a triple defect

et al. 2005

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We have manufactured and characterized a birefringent holey fiber of a new construction. The birefringence in this fiber is induced by the highly elliptical shape of the core, which consists of a triple defect in a hexagonal structure. Using a hybrid edge-nodal finite-element method, we calculated the spectral dependence of phase and group modal birefringence for spatial modes E11 and E21 in idealized and in real fiber, whose geometry we determined by using a scanning-electron microscope. Results of our calculations show that technological imperfections significantly affect the fiber's birefringence. Normalized cutoff wavelengths for higher-order modes relative to the filling factor were also determined for the idealized structure. We observed a significant disagreement between theoretical and experimental values of cutoff wavelengths, which was attributed to high confinement losses near the cutoff condition. We also measured the spectral dependence of the phase and the group modal birefringence for spatial modes E11 and E21. The measured parameters showed good agreement with the results of modeling.

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Fiber Bragg Gratings in Germanium-Doped Highly Birefringent Microstructured Optical Fibers

Geernaert

Nasiłowski

Chah

et al. 2008

IEEE Photon. Technol. Lett.

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Evaluation of Pseudomonas aeruginosa biofilm formation using piezoelectric tuning fork mass sensors

Waszczuk

Guła

Świątkowski

et al. 2012

Sensors and Actuators B: Chemical

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Effect of coupling between fundamental and cladding modes on bending losses in photonic crystal fibers

Olszewski¹,

Szpulak²,

Urbańczyk³

2005

Opt. Express

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The paper presents a fully vectorial analysis of bending losses in photonic crystal fibers employing edge/nodal hybrid elements and perfectly matched layers boundary conditions. The oscillatory character of losses vs. both the wavelength and the bending radius has been demonstrated. The shown oscillations originate from the coupling between the fundamental mode guided in the core and the gallery of cladding modes arising due to light reflection from the boundary between solid and holey part of the cladding.

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Temperature and pressure sensitivities of the highly birefringent photonic crystal fiber with core asymmetry

et al. 2005

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Sensing characteristics of the rocking filters in microstructured fibers optimized for hydrostatic pressure measurements

et al. 2012

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We report on the sensing characteristics of rocking filters fabricated in two microstructured fibers with enhanced polarimetric sensitivity to hydrostatic pressure. The filter fabricated in the first fiber shows a very high sensitivity to pressure ranging from 16.2 to 43.4 nm/MPa, depending on the resonance order and features an extremely low cross-sensitivity between pressure and temperature 28 ÷ 89 × 10(3) K/MPa. The filter fabricated in the second fiber has an extreme sensitivity to pressure ranging from -72.6 to -177 nm/MPa, but a less favorable cross-sensitivity between pressure and temperature of 1.05 ÷ 3.50 × 10(3) K/MPa. These characteristics allow using the rocking filters for pressure measurements with mbar resolution.

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J. Olszewski

Highly birefringent microstructured fibers with enhanced sensitivity to hydrostatic pressure

Plug&Play Fiber‐Coupled 73 kHz Single‐Photon Source Operating in the Telecom O‐Band

Experimental and theoretical investigations of birefringent holey fibers with a triple defect

Fiber Bragg Gratings in Germanium-Doped Highly Birefringent Microstructured Optical Fibers

Evaluation of Pseudomonas aeruginosa biofilm formation using piezoelectric tuning fork mass sensors

Effect of coupling between fundamental and cladding modes on bending losses in photonic crystal fibers

Temperature and pressure sensitivities of the highly birefringent photonic crystal fiber with core asymmetry

Sensing characteristics of the rocking filters in microstructured fibers optimized for hydrostatic pressure measurements

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