ULTRARAM: A Low-Energy, High-Endurance, Compound-Semiconductor Memory on Silicon
ULTRARAM: A Low-Energy, High-Endurance, Compound-Semiconductor Memory on Silicon
Published
| Article number | 2101103 |
|---|---|
| Journal publication date | 30/04/2022 |
| Journal | Advanced Electronic Materials |
| Issue number | 4 |
| Volume | 8 |
| Number of pages | 9 |
| Publication Status | Published |
| Early online date | 5/01/22 |
| Original language | English |
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ULTRARAM: A Low-Energy, High-Endurance, Compound-Semiconductor Memory on Silicon. / Hodgson, Peter; Lane, Dominic; Carrington, Peter et al.
In: Advanced Electronic Materials, Vol. 8, No. 4, 2101103, 30.04.2022.
Contribution to Journal/Magazine › Journal article › peer-review
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RIS
TY – JOUR
T1 – ULTRARAM
T2 – A Low-Energy, High-Endurance, Compound-Semiconductor Memory on Silicon
AU – Hodgson, Peter
AU – Lane, Dominic
AU – Carrington, Peter
AU – Delli, Evangelia
AU – Beanland, Richard
AU – Hayne, Manus
PY – 2022/4/30
Y1 – 2022/4/30
N2 – ULTRARAM is a nonvolatile memory with the potential to achieve fast, ultralow-energy electron storage in a floating gate accessed through a triple-barrier resonant tunneling heterostructure. Here its implementation is reported on a Si substrate; a vital step toward cost-effective mass production. Sample growth using molecular beam epitaxy commences with deposition of an AlSb nucleation layer to seed the growth of a GaSb buffer layer, followed by the III–V memory epilayers. Fabricated single-cell memories show clear 0/1 logic-state contrast after ≤10 ms duration program/erase pulses of ≈2.5 V, a remarkably fast switching speed for 10 and 20 µm devices. Furthermore, the combination of low voltage and small device capacitance per unit area results in a switching energy that is orders of magnitude lower than dynamic random access memory and flash, for a given cell size. Extended testing of devices reveals retention in excess of 1000 years and degradation-free endurance of over 107 program/erase cycles, surpassing very recent results for similar devices on GaAs substrates.
AB – ULTRARAM is a nonvolatile memory with the potential to achieve fast, ultralow-energy electron storage in a floating gate accessed through a triple-barrier resonant tunneling heterostructure. Here its implementation is reported on a Si substrate; a vital step toward cost-effective mass production. Sample growth using molecular beam epitaxy commences with deposition of an AlSb nucleation layer to seed the growth of a GaSb buffer layer, followed by the III–V memory epilayers. Fabricated single-cell memories show clear 0/1 logic-state contrast after ≤10 ms duration program/erase pulses of ≈2.5 V, a remarkably fast switching speed for 10 and 20 µm devices. Furthermore, the combination of low voltage and small device capacitance per unit area results in a switching energy that is orders of magnitude lower than dynamic random access memory and flash, for a given cell size. Extended testing of devices reveals retention in excess of 1000 years and degradation-free endurance of over 107 program/erase cycles, surpassing very recent results for similar devices on GaAs substrates.
KW – ULTRARAM
KW – Silicon
KW – Compound semiconductors
KW – Molecular beam epitaxy (MBE)
KW – memory
U2 – 10.1002/aelm.202101103
DO – 10.1002/aelm.202101103
M3 – Journal article
VL – 8
JO – Advanced Electronic Materials
JF – Advanced Electronic Materials
SN – 2199-160X
IS – 4
M1 – 2101103
ER –
Final published version, 1.55 MB, PDF document Available under license: CC BY: Creative Commons Attribution 4.0 International License
Final published version Licence: CC BY: Creative Commons Attribution 4.0 International License
Final published version Available under license: CC BY: Creative Commons Attribution 4.0 International License
