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Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride. / Orlov, O. M.; Gismatulin, A. A.; Gritsenko, V. A. et al.

In: Russian Microelectronics, Vol. 49, No. 5, 01.09.2020, p. 372-377.

Research output: Contribution to journalArticlepeer-review

Harvard

Orlov, OM, Gismatulin, AA, Gritsenko, VA & Mizginov, DS 2020, 'Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride', Russian Microelectronics, vol. 49, no. 5, pp. 372-377. https://doi.org/10.1134/S1063739720050078

APA

Orlov, O. M., Gismatulin, A. A., Gritsenko, V. A., & Mizginov, D. S. (2020). Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride. Russian Microelectronics, 49(5), 372-377. https://doi.org/10.1134/S1063739720050078

Vancouver

Orlov OM, Gismatulin AA, Gritsenko VA, Mizginov DS. Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride. Russian Microelectronics. 2020 Sept 1;49(5):372-377. doi: 10.1134/S1063739720050078

Author

Orlov, O. M. ; Gismatulin, A. A. ; Gritsenko, V. A. et al. / Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride. In: Russian Microelectronics. 2020 ; Vol. 49, No. 5. pp. 372-377.

BibTeX

@article{92a61de8fb55497aac5b9623aeb5f617,
title = "Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride",
abstract = "Silicon oxide and silicon nitride are two key dielectrics in silicon devices. The advantage of silicon nitride over other dielectrics is that silicon nitride is compatible with silicon technology. Despite numerous studies, the mechanism of charge transfer in the storage elements of resistive memory based on silicon nitride is still not clear. It is required to study in detail the mechanism of charge transfer in a memristor based on silicon nitride in order to further improve the cell information storage element and create a matrix of these elements. Metal–nitride–oxide–silicon (MNOS) structures that exhibit memristor properties are obtained using chemical vapor deposition at low pressure at 700°C. The fabricated structure of the resistive memory storage element based on metal–nitride–oxide–silicon does not require a molding procedure. In addition, such a memristor has a memory window of about five orders of magnitude. We establish that the main mechanism of charge transfer in the MNOS memristor in the high-resistance state is the current model with a limited spatial charge of the traps. In a low resistance state, the charge transfer mechanism is described by the current model with a limited spatial charge with filled traps. The trap{\textquoteright}s parameters are determined in a memristor based on silicon nitride in a high-resistance state.",
author = "Orlov, {O. M.} and Gismatulin, {A. A.} and Gritsenko, {V. A.} and Mizginov, {D. S.}",
year = "2020",
month = sep,
day = "1",
doi = "10.1134/S1063739720050078",
language = "English",
volume = "49",
pages = "372--377",
journal = "Russian Microelectronics",
issn = "1063-7397",
publisher = "Maik Nauka-Interperiodica Publishing",
number = "5",

}

RIS

TY - JOUR

T1 - Charge Transport Mechanism in a Formless Memristor Based on Silicon Nitride

AU - Orlov, O. M.

AU - Gismatulin, A. A.

AU - Gritsenko, V. A.

AU - Mizginov, D. S.

PY - 2020/9/1

Y1 - 2020/9/1

N2 - Silicon oxide and silicon nitride are two key dielectrics in silicon devices. The advantage of silicon nitride over other dielectrics is that silicon nitride is compatible with silicon technology. Despite numerous studies, the mechanism of charge transfer in the storage elements of resistive memory based on silicon nitride is still not clear. It is required to study in detail the mechanism of charge transfer in a memristor based on silicon nitride in order to further improve the cell information storage element and create a matrix of these elements. Metal–nitride–oxide–silicon (MNOS) structures that exhibit memristor properties are obtained using chemical vapor deposition at low pressure at 700°C. The fabricated structure of the resistive memory storage element based on metal–nitride–oxide–silicon does not require a molding procedure. In addition, such a memristor has a memory window of about five orders of magnitude. We establish that the main mechanism of charge transfer in the MNOS memristor in the high-resistance state is the current model with a limited spatial charge of the traps. In a low resistance state, the charge transfer mechanism is described by the current model with a limited spatial charge with filled traps. The trap’s parameters are determined in a memristor based on silicon nitride in a high-resistance state.

AB - Silicon oxide and silicon nitride are two key dielectrics in silicon devices. The advantage of silicon nitride over other dielectrics is that silicon nitride is compatible with silicon technology. Despite numerous studies, the mechanism of charge transfer in the storage elements of resistive memory based on silicon nitride is still not clear. It is required to study in detail the mechanism of charge transfer in a memristor based on silicon nitride in order to further improve the cell information storage element and create a matrix of these elements. Metal–nitride–oxide–silicon (MNOS) structures that exhibit memristor properties are obtained using chemical vapor deposition at low pressure at 700°C. The fabricated structure of the resistive memory storage element based on metal–nitride–oxide–silicon does not require a molding procedure. In addition, such a memristor has a memory window of about five orders of magnitude. We establish that the main mechanism of charge transfer in the MNOS memristor in the high-resistance state is the current model with a limited spatial charge of the traps. In a low resistance state, the charge transfer mechanism is described by the current model with a limited spatial charge with filled traps. The trap’s parameters are determined in a memristor based on silicon nitride in a high-resistance state.

UR - http://www.scopus.com/inward/record.url?scp=85091408935&partnerID=8YFLogxK

U2 - 10.1134/S1063739720050078

DO - 10.1134/S1063739720050078

M3 - Article

AN - SCOPUS:85091408935

VL - 49

SP - 372

EP - 377

JO - Russian Microelectronics

JF - Russian Microelectronics

SN - 1063-7397

IS - 5

ER -

ID: 25687260