Oleg V. Snigirev

Oleg V. Snigirev

Devices based on LTS and HTS
Head of the Laboratory, Professor, Head of the Semiconductors division

ISTINA
P: +7 (495) 939-30-00
3-79

Publications

Porokhov, N., Kalabukhov, A., Chukharkin, M., Maresov, A., Khrykin, D., Klenov, N., and Snigirev, O. The physical basis of the fabrication of the third generation of high-temperature superconducting wires on quartz substrates. MOSCOW UNIVERSITY PHYSICS BULLETIN 70, 2 (2015), 134–139. [ DOI ]

Порохов, Н., Калабухов, А., Чухаркин, М., Маресов, А., Хрыкин, Д., Кленов, Н., и Снигирев, О. Физические основы технологии создания высокотемпературных сверхпроводящих проводов третьего поколения на кварцевых подложках. Вестник Московского университета. Серия 3. Физика, астрономия, 2 (2015), 56–61. URL ]

Dagesyan, S., Stepanov, A., Soldatov, E., and Snigirev, O. Properties of extremely narrow gaps between electrodes of a molecular transistor. Journal of Superconductivity and Novel Magnetism (2014). [ DOI ]

Gerasimov, Y., Shorokhov, V., and Snigirev, O. Electron transport through thiolized gold nanoparticles in single-electron transistor. Journal of Superconductivity and Novel Magnetism (2014), 1–6. [ DOI ]

Сhukharkin, M., Kalaboukhov, A., Schnaiderman, J., Oisjoen, F., Jonsson, M., Xie, M., Snigirev, O., Winkler, D. Novel hts dc squid solutions for nmr applications. In Proceedings of the NATO Advanced Research Workshop on Magnetic Resonance Detection of Explosives and Ilicit Materials, NATO Science for Peace and Security Series B: Physics and Biophysics, pp. 151–159. [ DOI ]

Snigirev, O., Chukharkin, M., Porokhov, N., Rusanov, S., Kashin, V., Tsvetkov, V., Kalabukhov, A., and Winkler, D. Pulsed laser deposition of thin ybco films on faceted ysz single crystal fibers. Journal of Physics:Conference Series 507, PART 2 (2014). [ DOI ]

Blinova, Y., Kuznetsov, M., Galakhov, V., Sudareva, S., Krinitsina, T., Kuznetsova, E., Degtyarev, M., Snigirev, O., and Porokhov, N. X-ray photoelectron spectra and composition of yba2cu3o7 - δ films prepared by laser ablation. Physics of the Solid State 56, 4 (2014), 659–665. [ DOI ]

Сhukharkin, M., Kalaboukhov, A., Schnaiderman, J., Oisjoen, F., Jonsson, M., Xie, M., Snigirev, O., Winkler, D. Novel hts dc squid solutions for nmr applications. In Proceedings of the NATO Advanced Research Workshop on Magnetic Resonance Detection of Explosives and Ilicit Materials, NATO Science for Peace and Security Series B: Physics and Biophysics, Dordrecht, Netherlands, 3311GZ, pp. 151–159. [ DOI ]

Титова, С., Черепанова, Л., Блинова, Ю., Сударева, С., Дегтярев, М., Кузнецова, Е., Снигирев, О., и Порохов, Н. Термическая устойчивость пленок YBa2Cu3O7-δ, напыленных на текстурованные подложки Ni-W методом лазерной абляции. Физика Твердого Тела 55, 8 (2013), 1500–1503. [ URL ]

Chukharkin, M., Kalabukhov, A., Schneiderman, О., Öisjöen, F., Magnus, J., Xie, M., Snigirev, O., and Winkler, D.  Improvement of ultra-low field magnetic resonance recordings with a multilayer flux-transformer-based high-tc squid magnetometer. IEEE Transactions on Applied Superconductivity 23, 3 (2013), 1602704–1–1602704–4. [ DOI ]

Трифонов, А., Васильев, Р., Езубченко, И., Соколикова, М., Бритов, Д., Преснов, Д., и Снигирев, О. Исследование электронных свойств одиночных нанокристаллов СdTe и CdTe/CdSe в сканирующем туннельном микроскопе. Радиотехника, 5 (2013), 35–40. [ URL ]

Криницина, Т., Сударева, С., Блинова, Ю., Кузнецова, Е., Романов, Е., Дегтярев, М., Снигирев, О., Прохоров, Н., Раков, Д., и Белотелова, Ю. Структурное состояние образцов ВТСП проводников второгопоколения, полученных методом лазерной абляции. Физика Твердого Тела 55, 2 (2013), 227–233. [ URL ]

Чухаркин, М., Порохов, Н., Калабухов, А., Снигирев, О., Русанов, С., Кашин, В., Цветков, В., и Винклер, Д. Высокотемпературные сверхпроводящие пленки на фасетированных монокристалических нитях. Журнал радиоэлектроники (электронный журнал), 2 (2013), 1–13. [ URL ]

Герасимов, Я., Шорохов, В., Маресов, А., Солдатов, Е., и Снигирев, О. Исследование связи энергетических спектров молекул с транспортными характеристиками одноэлектронных транзисторов на их основе. Журнал радиоэлектроники (электронный журнал), 2 (2013). [ URL ]

Stepanov, A., Soldatov, E., and Snigirev, O. Fabrication of integrated electrodes of molecular transistor by lithographic techniques and electromigration. In Proc. SPIE 8700, International Conference Micro- and Nano-Electronics 2012 (2013), pp. 87000C–1–87000C–5. [ DOI ]

Gerasimov, Y., Shorokhov, V., Soldatov, E., and Snigirev, O. Gold nanoparticle single-electron transistor simulation. In Proc. SPIE 8700, International Conference Micro- and Nano-Electronics 2012, 870015 (2013). DOI ]

Езубченко, И., Трифонов, А., Осадько, И., Прохорова, И., Снигирев, О., и Солдатов, Е. Оптическое излучение нанокристаллов CdSe под действием туннельного тока сканирующего туннельного микроскопа. Известия РАН. Серия физическая 76, 12 (2012), 1465–1467.

Porokhov, N., Levin, E., Chukharkin, M., Rakov, D., Vorob'eva, A., Varlashkin, A., and Snigirev, O. High-temperature superconducting films on flexible substrates for flux transformers. Journal of Communications Technology and Electronics 57, 10 (2012), 1130–1137. [ DOI ]

Порохов, Н., Левин, Э., Чухаркин, М., Раков, Д., Воробьёва, А., Варлашкин, А., и Снигирёв, О. Высокотемпературные сверхпроводящие плёнки на гибких подложках для трансформатора магнитного потока. Радиотехника и электроника 57, 7 (2012), 1128–1138. [ DOI ]

Trifonov, A., Osad’ko, I., Ezubchenko, I., Prokhorova, I., and Snigirev, O. Electroluminescence of single cdse nanocrystals induced by scanning tunneling microscope. Optics Communications 285, 7 (2012), 1997–2000. [ DOI ]

Chukharkin, M., Kalabukhov, A., Schneiderman, J., Oisjoen, F., Snigirev, O., Lai, Z., and Winkler, D. Noise properties of high-T-c superconducting flux transformers fabricated using chemical-mechanical polishing. Applied Physics Letters 101, 4 (2012). [ DOI ]

Gerasimov, Y. S., Shorokhov, V., Maresov, A., Soldatov, E., and Snigirev, O. Calculation of the mutual capacitance of nanoobjects. Journal of Communications Technology and Electronics 56, 12 (2011), 1483–1489.

Герасимов, Я., Шорохов, В., Маресов, А., Солдатов, Е., and Снигирев, О. Расчет взаимной емкости нанообъектов. Радиотехника и электроника 56, 12 (2011), 1483–1489.

Fukumoto, S., Hayashi, M., Katsu, Y., Suzuki, M., Morita, R., Naganuma, Y., Hatsukade, Y., Tanaka, S., and Snigirev, O. Liquid-state nuclear magnetic resonance measurements for imaging using hts-rf-squid in ultra-low field. IEEE Transactions on Applied Superconductivity 21, 3 (2011), 522–525. [ DOI ]

Snigirev, O., Hayashi, M., Fukumoto, S., Hatsukade, Y., Katsu, Y., and Tanaka, S. Development of ultra low field nuclear magnetic resonance imaging system using hts rf squid. Journal of Superconductivity and Novel Magnetism 24, 1-2 (2011), 1033–1036. [ DOI ]

Stepanov, A., Soldatov, E., and Snigirev, O. Implementation of molecular transistor electrodes by electromigration. Journal of Superconductivity and Novel Magnetism 24, 1-2 (2011), 1087–1093. [ DOI ]

Stepanov, A., Soldatov, E., and Snigirev, O. Formation of molecular transistor electrodes by electromigration. In Proc. SPIE (2010), vol. 7521, pp. 752112–1–752112–8. [ DOI ]

Gerasimov, Y., Shorokhov, V., Soldatov, E., and Snigirev, O. Calculation of the characteristics of electron transport through molecular clusters. Proceedings of SPIE - The International Society for Optical Engineering 7521 (2010), 75210U–1–75210U–11. [ DOI ]

Burmistrov, E., Maslennikov, Y. V., Slobodchikov, V., Khanin, V., and Snigirev, O. High-sensitivity gradiometer based on three high-t-c squid magnetometers. Journal of Communications Technology and Electronics 55, 9 (2010), 1070–1075.

Burmistrov, E. V., Slobodchikov, V., Khanin, V., Maslennikov, Y. V., and Snigirev, O. Dc squid modulation electronics for operation with hts dc squid magnetometers in the unshielded environment. IEEE Transactions on Applied Superconductivity 19, 3 (2009), 206–209. DOI ]

Volkov, I., Snigirev, О., Maresov, A., Volkov, A., Torii, Y., and Tanaka, S. Squid-based relaxometric diagnostic of magnetic nanoparticles. Solid State Phenomena, 2009, vol. 152-153, pp.217-220 152 (2009), 217–220. [ DOI ]

Burmistrov, E., Slobodchikov, V., Khanin, V., Maslennikov, Y. V., and Snigirev, O. Modulation squid electronics working with high-t (c) squids in open space. Journal of Communications Technology and Electronics 53, 10 (2008), 1259–1265. [ DOI ]

Kalabukhov, A., Chukharkin, M., Deleniv, A., Winkler, D., Volkov, I., and Snigirev, O. Analysis of the possibility to amplify an rf signal with a superconducting quantum interference filter. Journal of Communications Technology and Electronics 53, 8 (2008), 934–940. [ DOI ]

Volkov, I., Chukharkin, M., Snigirev, O., Volkov, A., Tanaka, S., and Fourie, C. Determination of the anisotropy constant and saturation magnetization of magnetic nanoparticles from magnetization relaxation curves. J. Nanopart. Res 10, 3 (2008), 487–497. [ DOI ]

Varlashkin, A., Krasnosvobodtsev, S., Chukharkin, M., Snigirev, O., Tsikunov, A., and Shabanova, N. Deposition of smooth high-t-c superconducting films with a solid-state yag : Nd3+ laser. Technical Physics 52, 5 (2007), 660–662. [ DOI ]

Snigirev, O. V., Chukharkin, M. L., Kalabukhov, A. S., Tarasov, M. A., Deleniv, A. A., Mukhanov, O. A., and Winkler, D. Superconducting quantum interference filters as rf amplifiers. IEEE Transactions on Applied Superconductivity 17, 2 (2007), 718–721. [ DOI ]

Burmistrov, E., Dmitriev, P., Tarasov, M., Kalabukhov, A., Kovtonyuk, S., Gudoshnikov, S., Snigirev, O., Kuz’min, L., and Koshelets, V. A planar picoamperemeter based on a superconducting quantum interferometer. Journal of Communications Technology and Electronics 51, 11 (2006), 1319–1324. [ DOI ]

Volkov, I., Gudoshnikov, S., Usov, N., Volkov, A., Moskvina, M., Maresov, A., Snigirev, О., and Tanaka, S. Squid-measurements of relaxation time of Fe3O4 superparamagnetic nanoparticle ensembles. Journal of Magnetism and Magnetic Materials 300 (2006), e294–e297. [ DOI ]

Volkov, I., Chukharkin, M., Snigirev, O., Volkov, A., Moskvina, M., Gudoshnikov, S., and Kerimov, A. Hts squid microscopy for measuring the magnetization relaxation of magnetic nanoparticles. IEEE Transactions on Applied Superconductivity 15, 3 (2005), 3874–3878.

Andreenko, S., Snigirev, O., Maresov, A., Muck, M., and Scholz, F. A new software for the processing of squid-microscopy images. IEEE Transactions on Applied Superconductivity 15, 2 (2005), 692–695.

Shorokhov, V., Soldatov, E., and Snigirev, O. Theoretical study of characteristics of a molecular single-electron transistor. Thin Solid Films 464 (2004), 445–451.  [ DOI ]

Tarasov, M., Kalabukhov, A., Kovtonyuk, S., Lapitskaya, I., Gudoshnikov, S., Kiviranta, M., Snigirev, O., Kuz’min, L., and Seppa, H. A femtoamperemeter based on a superconducting quantum interferometer and a bulk transformer. Journal of Communications Technology and Electronics 48, 12 (2003), 1404–1409.

Volkov, I., Chuharkin, M., Snigirev, O., and Ranchinski, M. Yba2cu3ox submicron josephson junctions on bicrystal substrates. IEEE Transactions on Applied Superconductivity 13, 2 (2003), 861–864. [ DOI ]

Kalaboukhov, A., Tarasov, M., Lohmns, A., Ivanov, Z., and Snigirev, O. Properties of a high-t-c dc squid radiofrequency amplifier. IEEE Transactions on Applied Superconductivity 13, 2 (2003), 1039–1041. [ DOI ]

Gudoshnikov, S., Liubimov, B., Matveets, L., Snigirev, O., Maresov, A., Prokoshin, A., Borisov, V., and Usov, N. Study of amorphous ferromagnetic microwires using a scanning squid microscope. Physica C: Superconductivity and its Applications 372 (2002), 271–273. [ DOI ]

Gudoshnikov, S., Liubimov, B., Deryuzhkina, Y., Matveets, L., Snigirev, O., Kalabukhov, A., Ranchinski, M., Schmidl, F., and Seidel, P. Hts scanning squid microscope with high spatial resolution for room temperature samples. Physica C: Superconductivity and its Applications 372 (2002), 166–169. [ DOI ]

Kalabukhov, A., Tarasov, M., Stepantsov, E., Gevorgian, S., Deleniv, A., Ivanov, Z., Snigirev, O., Vendik, O., and Mukhanov, O. A high-t-c l-band squid amplifier combined with superconductive thin-film filters. Physica C: Superconductivity and its Applications 368, 1-4 (2002), 171–175. [ DOI ]

Gudoshnikov, S., Liubimov, B., Matveets, L., Mikhailenko, A., Deryuzhkina, Y., Sitnov, Y., and Snigirev, O. Flux guide for high-t-c squid microscope with high spatial resolution. Physica C: Superconductivity and its Applications 368, 1-4 (2002), 66–69. [ DOI ]

Tishin, A., Snigirev, O., Khomutov, G., Gudoshnikov, S., and Bohr, J. Magnetic volcanos in gadolinium langmuir-blodgett films. Journal of Magnetism and Magnetic Materials 234, 3 (2001), 499–504. [ DOI ]

Volkov, I., Kalabukhov, A., Snigirev, O., Zherikhin, A., and Mavrin, B. Carbon masks for the fabrication of submicron yba2cu3ox bridges and josephson junctions. Journal of Communications Technology and Electronics 46, 7 (2001), 822–825.

Gudoshnikov, S., Matveets, L., Migulin, V., Snigirev, O., and Tishin, A. High-resolution scanning magnetometry based on a superconducting quantum interferometer. Journal of Communications Technology and Electronics 46, 7 (2001), 729–740.

Volkov, I., Kalabukhov, A., Snigirev, O., and Zherikhin, A. Carbon masks for patterning of yba2cu3ox submicron josephson junctions. IEEE Transactions on Applied Superconductivity 11, 1 (2001), 292–295. [ DOI ]

Gudoshnikov, S., Rudenchik, P., Matveets, L., Snigirev, O., Liubimov, B., Perov, N., Gan'shina, E., Antonov, A., D'achkov, A., and Sedova, M. Squid microscope for magnetic structure visualization in magnetoimpedance elements. IEEE Transactions on Applied Superconductivity 11, 1 (2001), 223–225. [ DOI ]

Gudoshnikov, S., Deryuzkina, Y., Rudenchik, P., Sitnov, Y., Bondarenko, S., Shablo, A., Pavlov, P., Kalabukhov, A., Snigirev, O., and Seidel, P. Magnetic flux guide for high-resolution squid microscope. IEEE Transactions on Applied Superconductivity 11, 1 (2001), 219–222. [ DOI ]

Tarasov, M., Kalabukhov, A., Snigirev, O., Krasnosvobodtsev, S., and Stepantsov, E. Uhf amplifier based on a high-t-c dc squid with a microstrip input coupler. Journal of Communications Technology and Electronics 45, 9 (2000), 1033–1037.

Kirichenko, D., Pavolotskii, A., Prokhorova, I., and Snigirev, O. Characteristics of a thin-film sensor for a scanning squid microscope. Technical Physics 44, 7 (1999), 839–843.

Gudoshnikov, S., Matveets, L., Weidl, R., Dorrer, L., Seidel, P., Krasnosvobodtsev, S., Kalabukhov, A., and Snigirev, O. A direct readout high-t-c dc squid electronics with ac bias and a liquid-nitrogen-cooled preamplifier. IEEE Transactions on Applied Superconductivity 9, 2 (1999), 4397–4399. [ DOI ]

Kirichenko, D., Pavolotskij, A., Prokhorova, I., Snigirev, O., Mezzena, R., Vitale, S., Maslennikov, Y., and Beljaev, A. Advanced version of two stage dc squid-based amplifier. IEEE Transactions on Applied Superconductivity 9, 2 (1999), 2906–2908. [ DOI ]

Gudoshnikov, S., Kalabukhov, A., Chupakhin, S., Tishin, A., Snigirev, O., Bohr, J., Muck, M., Heiden, C., and Dechert, J. Magnetic properties of ho measured by a scanning squid microscope. IEEE Transactions on Applied Superconductivity 9, 2 (1999), 4385–4388. [ DOI ]

Snigirev, O. Super-sensitive squid magnetometry. Uspekhi Fizicheskikh Nauk 169, 2 (1999), 221–223.

Snigirev, O., Tishin, A., Andreev, K., Gudoshnikov, S., and Bohr, J. Magnetic properties of ultrathin ni films. Physics of the Solid State 40, 9 (1998), 1530–1533.