NAND flash forms the core of modern solid-state storage, which is critical for data-intensive AI applications, yet charge-trap NAND suffers rapid threshold-voltage (Vth) degradation under ionizing radiation, causing reliability challenges for space and defense applications. Here we show that ferroelectric field-effect transistors (FeFETs) with laminated gate stacks offer a promising route to achieving radiation resilience in vertical NAND technology. We demonstrate that large-memory-window, vertical NAND-compatible laminated poly-silicon-channel FeFETs with an 8 nm Hf0.5Zr0.5O2/3 nm Al2O3/8 nm Hf0.5Zr0.5O2 stack retain a full memory window and robust switching up to 10 Mrad(air) of the total ionizing dose (TID). Programmed and erased states show negligible TID-induced drift after 1 Mrad(air), while only the erased state degrades by ∼2 V at 10 Mrad(air). Technology computer-aided design (TCAD) modeling attributes these asymmetric shifts to state-dependent traps. Compared to charge-trap NAND, laminated FeFETs exhibit ∼30-fold lower Vth degradation per unit dose, positioning them as superior radiation-resilient storage candidates.
Enabling Radiation Hardness in Solid-State NAND Storage Utilizing a Laminated Ferroelectric Stack / Fernandes, L., Wodzro, S., Venkatesan, P., Ravikumar, P., Lee, M., Shon, M., Chakraborty, D., Song, T., Kang, S., Soliman, S., Tian, M., Yeager, J., Adler, J., Chen, J., Wang, Z., Wolfe, D., Yu, S., Padovani, A., Datta, S., Ray, B., et al.. - In: NANO LETTERS. - ISSN 1530-6984. - 26:10(2026), pp. 3390-3397. [10.1021/acs.nanolett.5c05947]
Enabling Radiation Hardness in Solid-State NAND Storage Utilizing a Laminated Ferroelectric Stack
Padovani, Andrea;
2026
Abstract
NAND flash forms the core of modern solid-state storage, which is critical for data-intensive AI applications, yet charge-trap NAND suffers rapid threshold-voltage (Vth) degradation under ionizing radiation, causing reliability challenges for space and defense applications. Here we show that ferroelectric field-effect transistors (FeFETs) with laminated gate stacks offer a promising route to achieving radiation resilience in vertical NAND technology. We demonstrate that large-memory-window, vertical NAND-compatible laminated poly-silicon-channel FeFETs with an 8 nm Hf0.5Zr0.5O2/3 nm Al2O3/8 nm Hf0.5Zr0.5O2 stack retain a full memory window and robust switching up to 10 Mrad(air) of the total ionizing dose (TID). Programmed and erased states show negligible TID-induced drift after 1 Mrad(air), while only the erased state degrades by ∼2 V at 10 Mrad(air). Technology computer-aided design (TCAD) modeling attributes these asymmetric shifts to state-dependent traps. Compared to charge-trap NAND, laminated FeFETs exhibit ∼30-fold lower Vth degradation per unit dose, positioning them as superior radiation-resilient storage candidates.
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(L. Fernandes - ACS-NL, 2026) published version.pdf
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