A single ion impinging on a thin silicon dioxide layer generates a number of electron/hole pairs proportional to its linear energy transfer coefficient. Defects generated by recombination can act as a conductive path for electrons that cross the oxide barrier, thanks to a multitrap-assisted mechanism. We present data on the dependence of this phenomenon on the oxide thickness by using floating gate memory arrays. The tiny number of excess electrons stored in these devices allows for extremely high sensitivity, impossible with any direct measurement of oxide leakage current. Results are of particular interest for next generation devices.
Subattoampere current induced by single ions in silicon oxide layers of nonvolatile memory cells / Cellere, G; Paccagnella, A; Larcher, Luca; Visconti, A; Bonanomi, M.. - In: APPLIED PHYSICS LETTERS. - ISSN 0003-6951. - STAMPA. - 88:19(2006), pp. 192909-192909-3. [10.1063/1.2194819]
Subattoampere current induced by single ions in silicon oxide layers of nonvolatile memory cells
LARCHER, Luca;
2006
Abstract
A single ion impinging on a thin silicon dioxide layer generates a number of electron/hole pairs proportional to its linear energy transfer coefficient. Defects generated by recombination can act as a conductive path for electrons that cross the oxide barrier, thanks to a multitrap-assisted mechanism. We present data on the dependence of this phenomenon on the oxide thickness by using floating gate memory arrays. The tiny number of excess electrons stored in these devices allows for extremely high sensitivity, impossible with any direct measurement of oxide leakage current. Results are of particular interest for next generation devices.
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