Institution
Moscow Institute of Physics and Technology
Education•Dolgoprudnyy, Russia•
About: Moscow Institute of Physics and Technology is a education organization based out in Dolgoprudnyy, Russia. It is known for research contribution in the topics: Laser & Large Hadron Collider. The organization has 8594 authors who have published 16968 publications receiving 246551 citations. The organization is also known as: MIPT & Moscow Institute of Physics and Technology (State University).
Topics: Laser, Large Hadron Collider, Electron, Plasma, Magnetic field
Papers published on a yearly basis
Papers
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TL;DR: In this paper, a globally consistent treatment of linearized gravity in the Randall-Sundrum background with matter on the brane is formulated, in which the transverse components of the metric are non-vanishing.
57 citations
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TL;DR: In this paper, the role of multipole lattice effects in resonant properties of underlying nanostructures and nanophotonic elements in detail is reviewed, and different effects related to the same and cross-multipole interactions in the arrays are considered.
Abstract: In this Perspective, we outline the recent progress, primary achievements, and further directions in the development of high refractive index nanostructures and metasurfaces. In particular, we review the role of multipole lattice effects in resonant properties of underlying nanostructures and nanophotonic elements in detail. Planar optical designs with efficient light control at the nanoscale can be engineered based on photonic lattices that operate in the translational regime between two and three dimensions. Such transdimensional lattices include 3D-engineered nanoantennas supporting multipole Mie resonances and arranged in the 2D arrays to harness collective effects in the nanostructure. Lattice effects in the periodic nanoparticle arrays have recently attracted a lot of attention as they enable not only spectrally narrow resonant features but also resonance position tuning over a broad range. The recent results indicate that different nanoparticle multipoles not only produce resonant spectral features but are also involved in the cross-multipole coupling, and these effects need to be accounted for in photonic designs. Multipole lattice phenomena provide an effective way to control nanoparticle resonances, facilitate excitation of additional multipoles through a cross-multipole coupling, and enable light localization in planar photonic elements. We review different effects related to the same- and cross-multipole interactions in the arrays. Both infinite and finite arrays, as well as lattices of complex-shape nanoparticles, which allow out-of-plane multipole excitations, are considered.
57 citations
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01 Nov 2017
TL;DR: This work is devoted to an identity document recognition system design for use in mobile phones and tablets using the computational capabilities of the device itself and experimental results are presented for an implemented commercial system "Smart IDReader" designed for identity documents recognition.
Abstract: This work is devoted to an identity document recognition system design for use in mobile phones and tablets using the computational capabilities of the device itself Key differences are discussed in relation to conservative cloud recognition systems which commonly use single images as an input by design A mobile recognition system chart is presented which is constructed with computational limitations in mind and which is implemented in a commercial solution An original approach designed to improve recognition precision and reliability using post-OCR results integration in video stream, as opposed to approaches which rely on frame image integration using "super-resolution" algorithms An interactive feedback between the system and its operator is discussed, such as automatic video stream recognition stopping decision Experimental results are presented for an implemented commercial system "Smart IDReader" designed for identity documents recognition
57 citations
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TL;DR: It is hypothesize that many lantibiotics exploit the conserved features of lipid-II along with characteristic modulation of the bacterial membrane as the “landing site”, which opens new opportunities for studies on lantIBiotics action and design of novel armament against resistant bacterial strains.
Abstract: Bacterial cell wall is targeted by many antibiotics. Among them are lantibiotics, which realize their function via interaction with plasma membrane lipid-II molecule — a chemically conserved part of the cell wall synthesis pathway. To investigate structural and dynamic properties of this molecule, we have performed a series of nearly microsecond-long molecular dynamics simulations of lipid-II and some of its analogs in zwitterionic single component and charged mixed simulated phospholipid bilayers (the reference and the mimic of the bacterial plasma membrane, respectively). Extensive analysis revealed that lipid-II forms a unique “amphiphilic pattern” exclusively on the surface of the simulated bacterial membrane (and not in the reference one). We hypothesize that many lantibiotics exploit the conserved features of lipid-II along with characteristic modulation of the bacterial membrane as the “landing site”. This putative recognition mechanism opens new opportunities for studies on lantibiotics action and design of novel armament against resistant bacterial strains.
57 citations
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Albert M. Sirunyan1, Robin Erbacher2, C. A. Carrillo Montoya3, Wagner Carvalho4 +2314 more•Institutions (156)
TL;DR: In this article, a measurement of WZ electroweak (EW) vector boson scattering is performed in the leptonic decay modes WZ→lνl′l′, where l,l′=e,μ.
57 citations
Authors
Showing all 8797 results
Name | H-index | Papers | Citations |
---|---|---|---|
Dominique Pallin | 132 | 1131 | 88668 |
Vladimir N. Uversky | 131 | 959 | 75342 |
Lee Sawyer | 130 | 1340 | 88419 |
Dmitry Novikov | 127 | 348 | 83093 |
Simon Lin | 126 | 754 | 69084 |
Zeno Dixon Greenwood | 126 | 1002 | 77347 |
Christian Ohm | 126 | 873 | 69771 |
Alexey Myagkov | 109 | 586 | 45630 |
Stanislav Babak | 107 | 308 | 66226 |
Alexander Zaitsev | 103 | 453 | 48690 |
Vladimir Popov | 102 | 1030 | 50257 |
Alexander Vinogradov | 96 | 410 | 40879 |
Gueorgui Chelkov | 93 | 321 | 41816 |
Igor Pshenichnov | 83 | 362 | 22699 |
Vladimir Popov | 83 | 370 | 26390 |