We investigate endurance degradation in hafnium oxide (HfO2)-based ferroelectric field effect transistors (FeFETs) by analyzing interface (Nit) and near-interface oxide traps (Nox) using a two-level charge pumping (CP) technique. After 10⁴ program (PG) / erase (ER) cycles at ±5 V, 100 ns, Nit increases by ~2×, and the memory window (MW) reduces from 1.2 V to 0.45 V. Temperature-dependent measurements reveal accelerated trap generation above 50 °C, with decreasing charge-pumping current (Formula presented)due to deeper oxide trap occupation. Pulse parameter tuning shows that longer rise/fall times, and shorter hold durations mitigate Nit accumulation and delay memory window collapse. The extracted average interface trap density (Dit) reaches ~4×1012 cm-2eV-1 after cycling. These results emphasize the role of trap engineering in improving FeFET endurance for scaled non-volatile memory applications.

Trapping Dynamics and Endurance in HfO2-FeFETs: An Insight From Charge Pumping / Rana Sk, Masud; Senapati, Asim; Kumar, Gautham; Raffel, Yannick; Seidel, Konrad; Das, Apu; Paul, Agniva; Lederer, Maximilian; Cheng Chen, Chun; Padovani, Andrea; Chakrabarti, Bhaswar; De, Sourav. - In: IEEE ELECTRON DEVICE LETTERS. - ISSN 0741-3106. - 46:11(2025), pp. 2014-2017. [10.1109/led.2025.3612323]

Trapping Dynamics and Endurance in HfO2-FeFETs: An Insight From Charge Pumping

Padovani, Andrea
;
2025

Abstract

We investigate endurance degradation in hafnium oxide (HfO2)-based ferroelectric field effect transistors (FeFETs) by analyzing interface (Nit) and near-interface oxide traps (Nox) using a two-level charge pumping (CP) technique. After 10⁴ program (PG) / erase (ER) cycles at ±5 V, 100 ns, Nit increases by ~2×, and the memory window (MW) reduces from 1.2 V to 0.45 V. Temperature-dependent measurements reveal accelerated trap generation above 50 °C, with decreasing charge-pumping current (Formula presented)due to deeper oxide trap occupation. Pulse parameter tuning shows that longer rise/fall times, and shorter hold durations mitigate Nit accumulation and delay memory window collapse. The extracted average interface trap density (Dit) reaches ~4×1012 cm-2eV-1 after cycling. These results emphasize the role of trap engineering in improving FeFET endurance for scaled non-volatile memory applications.
2025
46
11
2014
2017
2-s2.0-105017053813
Trapping Dynamics and Endurance in HfO2-FeFETs: An Insight From Charge Pumping / Rana Sk, Masud; Senapati, Asim; Kumar, Gautham; Raffel, Yannick; Seidel, Konrad; Das, Apu; Paul, Agniva; Lederer, Maximilian; Cheng Chen, Chun; Padovani, Andrea; Chakrabarti, Bhaswar; De, Sourav. - In: IEEE ELECTRON DEVICE LETTERS. - ISSN 0741-3106. - 46:11(2025), pp. 2014-2017. [10.1109/led.2025.3612323]
Rana Sk, Masud; Senapati, Asim; Kumar, Gautham; Raffel, Yannick; Seidel, Konrad; Das, Apu; Paul, Agniva; Lederer, Maximilian; Cheng Chen, Chun; Padova...espandi
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11380/1389048
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