The Compact Model Synthesis for the RADFET Device

Vadim Kuznetsov; Dmitrii Andreev; Vladimir Andreev; Sergei Piskunov; Anatoli I. Popov

doi:10.3390/technologies13110492

The Compact Model Synthesis for the RADFET Device

Vadim Kuznetsov
, Dmitrii Andreev
, Vladimir Andreev^*
, Sergei Piskunov^*
, Anatoli I. Popov

^*Šī darba korespondējošais autors

Bauman Moscow State Technical University

Zinātniskās darbības rezultāts: Devums žurnālam › Zinātniskais raksts (žurnālā) › koleģiāli recenzēts

7 Atsauces (Scopus)

Kopsavilkums

This article proposes a compact model for the radiation-sensitive field-effect transistor (RADFET). The model represents the basic I–V characteristics of the MOSFET device and includes the effects of threshold voltage shift as a function of absorbed dose and gate bias, gate tunneling current, gate radiation current, dose accumulation, and fading. It accurately represents high-field effects in the gate dielectric of the RADFET device. Both the Fowler–Nordheim gate tunneling current and the radiation-induced gate current are incorporated into the model. The model enables determination of the radiation-induced charge during RADFET operation under high-field injection conditions, thereby improving the precision of accumulated dose readout. The proposed model is fully compatible with SPICE-based circuit simulators and can represent any type of RADFET device, including those with high-k gate dielectrics. Furthermore, the model was developed entirely using open-source circuit simulation tools.

Oriģinālvaloda	Angļu
Raksta numurs	492
Žurnāls	Technologies
Sējums	13
Izdevuma numurs	11
DOIs	https://doi.org/10.3390/technologies13110492
Publikācijas statuss	Publicēts - nov. 2025

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title = "The Compact Model Synthesis for the RADFET Device",

abstract = "This article proposes a compact model for the radiation-sensitive field-effect transistor (RADFET). The model represents the basic I–V characteristics of the MOSFET device and includes the effects of threshold voltage shift as a function of absorbed dose and gate bias, gate tunneling current, gate radiation current, dose accumulation, and fading. It accurately represents high-field effects in the gate dielectric of the RADFET device. Both the Fowler–Nordheim gate tunneling current and the radiation-induced gate current are incorporated into the model. The model enables determination of the radiation-induced charge during RADFET operation under high-field injection conditions, thereby improving the precision of accumulated dose readout. The proposed model is fully compatible with SPICE-based circuit simulators and can represent any type of RADFET device, including those with high-k gate dielectrics. Furthermore, the model was developed entirely using open-source circuit simulation tools.",

keywords = "MOSFET, RADFET, circuit simulation, compact modeling",

author = "Vadim Kuznetsov and Dmitrii Andreev and Vladimir Andreev and Sergei Piskunov and Popov, \{Anatoli I.\}",

note = "Publisher Copyright: {\textcopyright} 2025 by the authors.",

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month = nov,

doi = "10.3390/technologies13110492",

language = "English",

volume = "13",

journal = "Technologies",

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T1 - The Compact Model Synthesis for the RADFET Device

AU - Kuznetsov, Vadim

AU - Andreev, Dmitrii

AU - Andreev, Vladimir

AU - Piskunov, Sergei

AU - Popov, Anatoli I.

PY - 2025/11

Y1 - 2025/11

N2 - This article proposes a compact model for the radiation-sensitive field-effect transistor (RADFET). The model represents the basic I–V characteristics of the MOSFET device and includes the effects of threshold voltage shift as a function of absorbed dose and gate bias, gate tunneling current, gate radiation current, dose accumulation, and fading. It accurately represents high-field effects in the gate dielectric of the RADFET device. Both the Fowler–Nordheim gate tunneling current and the radiation-induced gate current are incorporated into the model. The model enables determination of the radiation-induced charge during RADFET operation under high-field injection conditions, thereby improving the precision of accumulated dose readout. The proposed model is fully compatible with SPICE-based circuit simulators and can represent any type of RADFET device, including those with high-k gate dielectrics. Furthermore, the model was developed entirely using open-source circuit simulation tools.

AB - This article proposes a compact model for the radiation-sensitive field-effect transistor (RADFET). The model represents the basic I–V characteristics of the MOSFET device and includes the effects of threshold voltage shift as a function of absorbed dose and gate bias, gate tunneling current, gate radiation current, dose accumulation, and fading. It accurately represents high-field effects in the gate dielectric of the RADFET device. Both the Fowler–Nordheim gate tunneling current and the radiation-induced gate current are incorporated into the model. The model enables determination of the radiation-induced charge during RADFET operation under high-field injection conditions, thereby improving the precision of accumulated dose readout. The proposed model is fully compatible with SPICE-based circuit simulators and can represent any type of RADFET device, including those with high-k gate dielectrics. Furthermore, the model was developed entirely using open-source circuit simulation tools.

KW - MOSFET

KW - RADFET

KW - circuit simulation

KW - compact modeling

UR - https://www.scopus.com/pages/publications/105023145028

U2 - 10.3390/technologies13110492

DO - 10.3390/technologies13110492

M3 - Article

AN - SCOPUS:105023145028

SN - 2227-7080

VL - 13

JO - Technologies

JF - Technologies

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ER -

The Compact Model Synthesis for the RADFET Device

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