Персона: Образцов, Иван Сергеевич
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Институт нанотехнологий в электронике, спинтронике и фотонике
Институт ИНТЭЛ занимается научной деятельностью и подготовкой специалистов в области исследования физических принципов, проектирования и разработки технологий создания компонентной базы электроники гражданского и специального назначения, а также построения современных приборов на её основе.
Наша основная цель – это создание и развитие научно-образовательного центра мирового уровня в области наноструктурных материалов и устройств электроники, спинтроники, фотоники, а также создание эффективной инновационной среды в области СВЧ-электронной и радиационно-стойкой компонентной базы, источников ТГц излучения, ионно-кластерных технологий материалов.
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Иван Сергеевич
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- ПубликацияОткрытый доступThermal Conductivity Gas Sensors for High-Temperature Applications(2024) Samotaev, N.; Podlepetsky, B.; Mashinin, M.; Ivanov, I.; Obraztsov, I.; Oblov, K.; Dzhumaev, P.; Самотаев, Николай Николаевич; Подлепецкий, Борис Иванович; Машинин, Михаил Олегович; Иванов, Игорь Александрович; Образцов, Иван Сергеевич; Облов, Константин Юрьевич; Джумаев, Павел СергеевичThis paper describes a fast and flexible microfabrication method for thermal conductivity gas sensors useful in high-temperature applications. The key parts of the sensor, the microheater and the package, were fabricated from glass-coated platinum wire and the combination of laser micromilling (ablation) of already-sintered monolithic ceramic materials and thick-film screen-printing technologies. The final thermal conductivity gas sensor was fabricated in the form of a complete MEMS device in a metal ceramic package, which could be used as a compact miniaturized surface-mounted device for soldering to standard PCB. Functional test results of the manufactured sensor are presented, demonstrating their full suitability for gas sensing applications and indicating that the obtained parameters are at a level comparable to those of standard industrially produced sensors. The results of the design and optimization principles of applied methods are discussed with regard to possible wider applications in thermal gas sensor prototyping in the future. The advantage of the developed sensors is their ability to operate in air environments under high temperatures of 900 ‚шC and above. The sensor element material and package metallization were insensitive to oxidation compared with classical sensor-solution-based metalў??glass packages and silicone MEMS membranes, which exhibit mechanical stress at temperatures above 700 ‚шC.
- ПубликацияТолько метаданныеSilicon MEMS Thermocatalytic Gas Sensor in Miniature Surface Mounted Device Form(2021) Samotaev, N.; Samotaev, N; Dzhumaev, P.; Oblov, K.; Pisliakov, A.; Самотаев, Николай Николаевич; Джумаев, Павел Сергеевич; Облов, Константин Юрьевич; Образцов, Иван СергеевичA reduced size thermocatalytic gas sensor was developed for the detection of methane over the 20% of the explosive concentration. The sensor chip is formed from two membranes with a 150 mu m diameter heated area in their centers and covered with highly dispersed nano-sized catalyst and inert reference, respectively. The power dissipation of the chip is well below 70 mW at the 530 degrees C maximum operation temperature. The chip is mounted in a novel surface mounted metal-ceramic sensor package in the form-factor of SOT-89. The sensitivity of the device is 10 mV/v%, whereas the response and recovery times without the additional carbon filter over the chip are <500 ms and <2 s, respectively. The tests have shown the reliability of the new design concerning the hotplate stability and massive encapsulation, but the high degradation rate of the catalyst coupled with its modest chemical power limits the use of the sensor only in pulsed mode of operation. The optimized pulsed mode reduces the average power consumption below 2 mW.