The Effect of Heavy-Ion Strikes on Charge Trap Memory Arrays With Analog State Programmability

T. Patrick Xiao; Christopher H. Bennett; Ryan Dempsey; Donald Wilson; Joshua Joffrion; Darlene M. Udoni; A. Alec Talin; Vineet Agrawal; Helmut Puchner; Matthew J. Marinella; Sapan Agarwal; David R. Hughart

doi:10.1109/TNS.2024.3505962

The Effect of Heavy-Ion Strikes on Charge Trap Memory Arrays With Analog State Programmability

T. Patrick Xiao, Christopher H. Bennett, Ryan Dempsey, Donald Wilson, Joshua Joffrion, Darlene M. Udoni, A. Alec Talin, Vineet Agrawal, Helmut Puchner, Matthew J. Marinella, Sapan Agarwal, David R. Hughart

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

Single-event effects (SEEs) induced by heavy ions were characterized on 32 distinct conductance states in 40-nm silicon-oxide–nitride-oxide–silicon (SONOS) charge-trap memory. These states were programmed onto three chips, each containing 256K SONOS memory devices in an array that was optimized for analog in-memory computing (IMC) operations. Spatially resolved measurements of heavy-ion effects on analog states reveal that the energy deposited by an ion is distributed across multiple adjacent memory cells, inducing a smooth tail in the memory state distributions. Ion-induced state shifts also show a strong dependence on the electric field across the tunnel oxide. Following radiation, SONOS devices that were struck by heavy ions showed no evidence of permanent damage that led to any observable degradation in long-term data retention properties. This resilience is likely intrinsic to the charge storage mechanism in SONOS memory and helps enable its reliable use in space for both data storage and analog IMC applications.

Original language	English (US)
Pages (from-to)	1375-1383
Number of pages	9
Journal	IEEE Transactions on Nuclear Science
Volume	72
Issue number	4
DOIs	https://doi.org/10.1109/TNS.2024.3505962
State	Published - 2025
Externally published	Yes

Keywords

Analog computing
charge trap memory
flash memory
heavy-ion irradiation
in-memory computing (IMC)
silicon-oxide–nitride-oxide–silicon (SONOS)
single-event effects (SEEs)
single-event upset

ASJC Scopus subject areas

Nuclear and High Energy Physics
Nuclear Energy and Engineering
Electrical and Electronic Engineering

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10.1109/TNS.2024.3505962

Cite this

Xiao, T. P., Bennett, C. H., Dempsey, R., Wilson, D., Joffrion, J., Udoni, D. M., Alec Talin, A., Agrawal, V., Puchner, H., Marinella, M. J., Agarwal, S., & Hughart, D. R. (2025). The Effect of Heavy-Ion Strikes on Charge Trap Memory Arrays With Analog State Programmability. IEEE Transactions on Nuclear Science, 72(4), 1375-1383. https://doi.org/10.1109/TNS.2024.3505962

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abstract = "Single-event effects (SEEs) induced by heavy ions were characterized on 32 distinct conductance states in 40-nm silicon-oxide–nitride-oxide–silicon (SONOS) charge-trap memory. These states were programmed onto three chips, each containing 256K SONOS memory devices in an array that was optimized for analog in-memory computing (IMC) operations. Spatially resolved measurements of heavy-ion effects on analog states reveal that the energy deposited by an ion is distributed across multiple adjacent memory cells, inducing a smooth tail in the memory state distributions. Ion-induced state shifts also show a strong dependence on the electric field across the tunnel oxide. Following radiation, SONOS devices that were struck by heavy ions showed no evidence of permanent damage that led to any observable degradation in long-term data retention properties. This resilience is likely intrinsic to the charge storage mechanism in SONOS memory and helps enable its reliable use in space for both data storage and analog IMC applications.",

keywords = "Analog computing, charge trap memory, flash memory, heavy-ion irradiation, in-memory computing (IMC), silicon-oxide–nitride-oxide–silicon (SONOS), single-event effects (SEEs), single-event upset",

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The Effect of Heavy-Ion Strikes on Charge Trap Memory Arrays With Analog State Programmability

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