Infocommunications and Radio Technologies Infocommunications and Radio Technologies ИНФОКОММУНИКАЦИОННЫЕ И РАДИОЭЛЕКТРОННЫЕ ТЕХНОЛОГИИ 2587-9936 52937 Электроника, фотоника, приборостроение и связь (2.2) ELECTRONICS, PHOTONICS, INSTRUMENTATION AND COMMUNICATIONS (2.2) Электроника, фотоника, приборостроение и связь (2.2) Analysis of a Vacuum Resonant-Tunneling Triode Анализ вакуумного резонансно-туннельного триода Давидович Михаил Владимирович Davidovich Michael V davidovichmv@info.sgu.ru Колесов Герман Николаевич Kolesov German N Саяпин Кирилл Александрович Sayapin Kirill A Саратовский национальный исследовательский государственный университет им. Н.Г. Чернышевского ru Saratov National Research State University named after N.G. Chernyshevsky ru Саратовский национальный исследовательский государственный университет им. Н.Г. Чернышевского ru Saratov National Research State University named after N.G. Chernyshevsky ru Саратовский национальный исследовательский государственный университет им. Н.Г. Чернышевского ru Saratov National Research State University named after N.G. Chernyshevsky ru 25 12 2021 25 12 2021 4 4 279 291 20 12 2021 https://rusjbpc.ru/en/nauka/article/52937/view

Предложены стационарная и нестационарная модели расчета туннельного тока вакуумного резонансно-туннельного триода с управляющей сеткой. Стационарная модель основана на решении стационарного уравнения Шрёдингера матричным методом и методом множественных изображений с расчетом профиля потенциала в конструкции, имеющей несколько электродов.

Stationary and non-stationary models are proposed for calculating the tunneling current of a vacuum resonant-tunneling triode with a control grid. The stationary model is based on the solution of the stationary Schrodinger equation by the matrix method with the calculation of the potential profile in a structure having several electrodes by the method of multiple images.

 туннелирование автоэлектронная эмиссия резонансный туннельный транзистор уравнение Шрёдингера уравнение Пуассона tunneling field emission resonant tunnel transistor Schrodinger equation Poisson equation This work was supported by grant from the Ministry of Education and Science of the Russian Federation within the framework of the State task (project No. FSRR-2020-0004).

Fursey G. N. Field emission in vacuum micro-electronics. NY : Kluwer Academic Plenum Publishers ; Springer, 2005. 205 p. Fursey G. N. Field emission in vacuum micro-electronics. NY : Kluwer Academic Plenum Publishers ; Springer, 2005. 205 p. Проскуровский Д. И. Эмиссионная электроника. Томск : ТГУ, 2010. С. 154-233. Proskurovskiy D. I. Emissionnaya elektronika. Tomsk : TGU, 2010. S. 154-233. Forbes R. G., Xanthakis J. P., Low-macroscopic-field electron emission from carbon films and other electrically nanostructured heterogeneous materials : hypotheses about emission mechanism // Solid-State Electronics. 2001. Vol. 45, No. 6. P. 779-808. Forbes R. G., Xanthakis J. P., Low-macroscopic-field electron emission from carbon films and other electrically nanostructured heterogeneous materials : hypotheses about emission mechanism // Solid-State Electronics. 2001. Vol. 45, No. 6. P. 779-808. Davidovich M. V., Yafarov R. K., Doronin D. M. Electron tunneling in the presence of dielectric film on the cathode. In : 2011 21st International Crimean Conference “Microwave & Telecommunication Technology” (CriMiCo’2010). Sevastopol, 2010. P. 733-734. Davidovich M. V., Yafarov R. K., Doronin D. M. Electron tunneling in the presence of dielectric film on the cathode. In : 2011 21st International Crimean Conference “Microwave & Telecommunication Technology” (CriMiCo’2010). Sevastopol, 2010. P. 733-734. Davidovich M. V., Bushuev N. A. Field Emission in Diode and Triode Vacuum Nanostructures. In : 2014 Tenth International Vacuum electron Sources Conference and Second International Conference on Emission Electronics. Saint-Petersburg, Saint-Petersburg State University, 2014. P. 58-59. Davidovich M. V., Bushuev N. A. Field Emission in Diode and Triode Vacuum Nanostructures. In : 2014 Tenth International Vacuum electron Sources Conference and Second International Conference on Emission Electronics. Saint-Petersburg, Saint-Petersburg State University, 2014. P. 58-59. Davidovich M. V., Bushuev N. A., Yafarov R. K. Tunnel Current in the Presence of Nanosized Film at the Cathode. In : 2014 Tenth International Vacuum electron Sources Conference and Second International Conference on Emission Electronics, Saint-Petersburg, Saint-Petersburg State University, 2014. P. 67-68. Davidovich M. V., Bushuev N. A., Yafarov R. K. Tunnel Current in the Presence of Nanosized Film at the Cathode. In : 2014 Tenth International Vacuum electron Sources Conference and Second International Conference on Emission Electronics, Saint-Petersburg, Saint-Petersburg State University, 2014. P. 67-68. Davidovich M. V., Bushuev N. A. The field emission electron gun with wide and thin ribbon bean. In : 25th Int. Crimean Conf. “Microwave and Telecommunication Technology” (CriMiCo’2015). Sevastopol, 2015. P. 145-146. Davidovich M. V., Bushuev N. A. The field emission electron gun with wide and thin ribbon bean. In : 25th Int. Crimean Conf. “Microwave and Telecommunication Technology” (CriMiCo’2015). Sevastopol, 2015. P. 145-146. Davidovich M. V., Yafarov R. K. Pulse and static field emission VAC of carbon nanoclaster structures: experiment and its interpretation // Technical Physics. 2019. Vol. 64, No. 8. P. 1210-1220. Davidovich M. V., Yafarov R. K. Pulse and static field emission VAC of carbon nanoclaster structures: experiment and its interpretation // Technical Physics. 2019. Vol. 64, No. 8. P. 1210-1220. Davidovich M. V., Yafarov R. K. Field-emission staggered structure based on diamond-graphite clusters // Technical Physics. 2018. Vol. 63, No. 2. P. 274-284. Davidovich M. V., Yafarov R. K. Field-emission staggered structure based on diamond-graphite clusters // Technical Physics. 2018. Vol. 63, No. 2. P. 274-284. Simmons J. G. Generalized formula for the electric tunnel effect between similar electrodes separated by a thin insulating film //j. Appl. Phys. 1963. Vol. 34, No. 6. P. 1793-1803. Simmons J. G. Generalized formula for the electric tunnel effect between similar electrodes separated by a thin insulating film //j. Appl. Phys. 1963. Vol. 34, No. 6. P. 1793-1803. Davidovich M. V. Time-dependent resonant tunneling in a double-barrier diode structure // Jetp Lett. 2019. Vol. 110. P. 472-480. Davidovich M. V. Time-dependent resonant tunneling in a double-barrier diode structure // Jetp Lett. 2019. Vol. 110. P. 472-480.