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Quasiperiodic one-dimensional photonic crystals with adjustable multiple photonic bandgaps / A. M. Vyunishev [et al.] // Opt. Lett. - 2017. - Vol. 42, Is. 18. - P. 3602-3605, DOI 10.1364/OL.42.003602. - Cited References: 27. - Government of Krasnoyarsk Territory, Krasnoyarsk Region Science and Technology Support Fund (16-42-243065); Russian Foundation for Basic Research (RFBR) (16-02-01100); Scholarship of the President of the Russian Federation (SP-3372.2015.5, SP-227.2016.5). The authors thank Prof. T. V. Murzina, M. Y. Shalaginov, and Prof. V. M. Shalaev for help and fruitful discussions. . - ISSN 0146-9592
Аннотация: We propose an elegant approach to produce photonic bandgap (PBG) structures with multiple photonic bandgaps by constructing quasiperiodic photonic crystals (QPPCs) composed of a superposition of photonic lattices with different periods. Generally, QPPC structures exhibit both aperi-odicity and multiple PBGs due to their long-range order. They are described by a simple analytical expression, instead of quasiperiodic tiling approaches based on substitution rules. Here we describe the optical properties of QPPCs exhibiting two PBGs that can be tuned independently. PBG interband spacing and its depth can be varied by choosing appropriate reciprocal lattice vectors and their amplitudes. These effects are confirmed by the proof-of-concept measurements made for the porous silicon-based QPPC of the appropriate design. © 2017 Optical Society of America.

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Держатели документа:
Kirensky Institute of Physics, Federal Research Center KSC SB RAS, Krasnoyarsk, Russian Federation
Institute of Engineering Physics and Radio Electronics, Siberian Federal University, Krasnoyarsk, Russian Federation
Institute of Nanotechnology, Spectroscopy and Quantum Chemistry, Siberian Federal University, Krasnoyarsk, Russian Federation
Department of Physics, M.V. Lomonosov Moscow State University, Moscow, Russian Federation

Доп.точки доступа:
Vyunishev, A. M.; Вьюнышев, Андрей Михайлович; Pankin, P. S.; Панкин, Павел Сергеевич; Svyakhovskiy, S. E.; Timofeev, I. V.; Тимофеев, Иван Владимирович; Vetrov, S. Ya.; Ветров, Степан Яковлевич
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    Revisiting the BaBiO3 semiconductor photocatalyst: synthesis, characterization, electronic structure, and photocatalytic activity / D. S. Shtarev, A. V. Shtareva, R. Kevorkyants [et al.] // Photochem. Photobiol. Sci. - 2021. - Vol. 20, Is. 9. - P. 1147-1160, DOI 10.1007/s43630-021-00086-y. - Cited References: 48. - We wish to thank the Russian Science Foundation for a Grant (Project No. 19-73-10013) in support of our study. The authors are also grateful to the staff of the following Institutes/Centers for their valuable technical assistance and in providing the needed equipment: (i) the Khabarovsk Innovation and Analytical Center of the Yu. A. Kosygin Institute of Tectonics and Geophysics FEB RAS; and (ii) the Resource Centers of the Research Park at Saint-Petersburg State University, especially the Center for Physical Methods of Surface Investigation and the Nanophotonics Center. One of us (NS) is grateful to the staff of the PhotoGreen Laboratory of the University of Pavia, Italy, for their continued hospitality . - ISSN 1474-905X. - ISSN 1474-9092
   Перевод заглавия: Новый анализ полупроводникового фотокатализатора BaBiO3: синтез, характеристика, электронная структура и фотокаталитическая активность

РУБ Biochemistry & Molecular Biology + Biophysics + Chemistry, Physical
Рубрики:
RHODAMINE-B
   OXIDE
   DRIVEN
   SUPERCONDUCTIVITY
   PSEUDOPOTENTIALS
Кл.слова (ненормированные):
Barium bismuthate -- Visible-light-active photocatalyst -- Photocatalytic activity -- Bandgaps -- Flatband potentials
Аннотация: This article revisits the properties of BaBiO3 examined extensively in the last two decades because of its electronic properties as a superconductor and as a semiconductor photocatalyst. Solid-state syntheses of this bismuthate have often involved BaCO3 as the barium source, which may lead to the formation of BaBiO3/BaCO3 heterostructures that could have an impact on the electronic properties and, more importantly, on the photocatalytic activity of this bismuthate. Accordingly, we synthesized BaBiO3 by a solid-state route to avoid the use of a carbonate; it was characterized by XRD, SEM, and EDX, while elemental mapping characterized the composition and the morphology of the crystalline BaBiO3 and its thin films with respect to structure, optoelectronic, and photocatalytic properties. XPS, periodic DFT calculations, and electrochemical impedance spectroscopy ascertained the electronic and electrical properties, while Raman and DRS spectroscopies assessed the relevant optical properties. The photocatalytic activity was determined via the degradation of phenol in aqueous media. Although some results accorded with earlier studies, the newer electronic structural data on this bismuthate, together with the photocatalytic experiments carried out in the presence of selective radical trapping agents, led to elucidating some of the mechanistic details of the photocatalytic processes that previous views of the BaBiO3 band structure failed to address or clarify. Analytical refinement of the XRD data inferred the as-synthesized BaBiO3 adopted the C2/m symmetry rather than the I2/m structure reported earlier, while Tauc plots from DRS spectra yielded a bandgap of 2.05 eV versus the range of 1.1–2.25 eV reported by others; the corresponding flatband potentials were 1.61 eV (EVB) and − 0.44 eV (ECB). The photocatalytic activity of BaBiO3 was somewhat greater than that of the well-known Evonik P25 TiO2 photocatalyst under comparable experimental conditions.

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Держатели документа:
Far Eastern Fed Univ, Lab Thin Film Technol, Ajax Bay 10, Vladivostok 690922, Russia.
St Petersburg State Univ, Lab Thotoact Nanocomposite Mat, Ulyanovskaya 1, St Petersburg 198504, Russia.
Far Eastern State Transport Univ, Serysheva 47, Khabarovsk 680021, Russia.
Kirensky Inst Phys, Akad Gorodok 50,Bld 38, Krasnoyarsk 660036, Russia.
Siberian Fed Univ, Svobodny 79, Krasnoyarsk 660041, Russia.
Univ Pavia, PhotoGreen Lab, Dipartimento Chim, Via Taramelli 12, I-27100 Pavia, Italy.

Доп.точки доступа:
Shtarev, Dmitry S.; Shtareva, Anna, V; Kevorkyants, Ruslan; Molokeev, M. S.; Молокеев, Максим Сергеевич; Serpone, Nick; Russian Science FoundationRussian Science Foundation (RSF) [19-73-10013]
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Properties of GdSF and phase diagram of the GdF3 - Gd2S3 system / M. U. Abulkhaev, M. S. Molokeev, A. S. Oreshonkov [и др.] // J. Solid State Chem. - 2023. - Vol. 322. - Ст. 123991, DOI 10.1016/j.jssc.2023.123991. - Cited References: 44. - The authors of the article are grateful to P.P. Fedorov for valuable critical comments on the manuscript. - This research was funded by the Tyumen Oblast Government, as a part of the West-Siberian Interregional Science and Education Center’s project No. 89-DON (3) . - ISSN 0022-4596. - ISSN 1095-726X
Кл.слова (ненормированные):
Gadolinium fluorosulfide -- Optical properties -- Electronic structure -- Thermal properties -- System phase diagram -- Tauc plot -- Direct and indirect bandgaps
Аннотация: The objectives of this study were to refine the phase diagram of the GdF3-Gd2S3 system and to calculate their liquidus, and to synthesize GdSF and to study their properties. The GdSF compound (ST PbFCl, P4/nmm, a (Å) 3.83006(17), c (Å) 6.8529(3), has an optical band gap for a direct interband transition of 2.56 eV and is characterized by a pronounced increase in the Kubelka-Munk function in the region of this transition. Direct optical bandgap of GdSF is measured to be equal to 2.77 eV. Two indirect bandgaps are detected to be 1.54 and 2.4 eV. Meta-GGA simulations of band structure predicting 1.481 eV direct bandgap of GdSF are in good agreement with these features of the experimental absorption spectrum. To explain this complicated case, we argue that formally direct optical transitions to highly dispersive subbands contribute not to direct but to indirect bandgaps measured by Tauc analysis. The GdSF compound melts incongruently with the formation of a melt and γ-Gd2S3 compound at t = 1280 ± 2°С, ΔН = 40.6 ± 2.8 kJ/mol, ΔS = 26.1 ± 1.8 J/mol∗K. The eutectic has a composition of 13 mol.% Gd2S3 (0.74 GdF3 + 0.26 GdSF), the melting characteristics of the eutectic are 1182 ± 2°С, ΔН = 36.2 ± 2.5 kJ/mol, ΔS = 24.9 ± 1.7 J/mol∗K. In the system GdF3 - Gd2S3 the balance equations for five phase transformations recorded by the DSC method were compiled. Convergence was achieved in the liquidus of the system constructed according to DSC data and calculated with the use of the Redlich-Kister equation.

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Держатели документа:
Tyumen State University, Tyumen, Volodarsky str. 6, 625003, Russia
Kirensky Institute of Physics, Federal Research Center KSC SB RAS, Krasnoyarsk, Akademgorodok str. 50, Building 38, 660036, Russia
Siberian Federal University, Krasnoyarsk, Svobodnyj av. 79, 660079, Russia
Department of Physical and Applied Chemistry, Kurgan State University, Sovetskaya str. 63/4, Kurgan, 640020, Russia
Institute of Solid State Chemistry, Ural Branch, Russian Academy of Sciences, Ekaterinburg, Pervomaiskaya str. 91, 620990, Russia

Доп.точки доступа:
Abulkhaev, M. U.; Molokeev, M. S.; Молокеев, Максим Сергеевич; Oreshonkov, A. S.; Орешонков, Александр Сергеевич; Aleksandrovsky, A. S.; Александровский, Александр Сергеевич; Kertman, A. V.; Kamaev, D. N.; Trofimova, O. V.; Elyshev, A. V.; Andreev, O. V.
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