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A. V. Filimonov

Bio: A. V. Filimonov is an academic researcher from Russian Academy of Sciences. The author has co-authored 1 publications. Previous affiliations of A. V. Filimonov include Saint Petersburg State Polytechnic University.

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TL;DR: In this paper, the structure of the chaotic potential caused by the electrostatic field of charged dislocations in group III-nitride heterojunctions is investigated, taking into account the spatial dispersion of the dielectric response of a two-dimensional electron gas.
Abstract: The structure of the chaotic potential caused by the electrostatic field of charged dislocations in group III-nitride heterojunctions is investigated. Taking into account the spatial dispersion of the dielectric response of a two-dimensional electron gas, the amplitude and scale of the chaotic potential in the junction plane are determined. It is shown that the parameters of the chaotic potential depend on the density of surface states and the concentration of dislocations.

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TL;DR: In this article , an intermodal fiber interferometer using the light from an incoherent broadband source has been considered analytically and implemented as a laboratory device, where the use of an optical spectrum analyzer and correlation functions approach in extracting the utility signal made it possible to achieve a linear response to the measured external perturbation and effective fading mitigation.
Abstract: An intermodal fiber interferometer using the light from an incoherent broadband source has been considered analytically and implemented as a laboratory device. It was shown that this optical scheme could be used to measure external perturbations that cause a change in the optical length of a multimode fiber. The use of an optical spectrum analyzer and correlation functions approach in extracting the utility signal made it possible to achieve a linear response to the measured external perturbation and effective fading mitigation. A pair of integral coefficients was introduced: the contrast coefficient for characterization of the coherency of the operation regime, and the fading coefficient for estimating the signal stability against non-signal parasitic influences. Analytical expressions for the utility signal parameters were derived in dependence on the parameters of the light source, multimode fiber, and optical spectrum analyzer. The relationships among fiber length, width of the light source spectrum, and frequency resolution of the optical spectrum analyzer were stated for the optimum regime of interferometer operation. The simulation of the external perturbations performed at the elaborated device proved the applicability of the proposed scheme as a sensor of various physical quantities.