2018 IEEE International Electron Devices Meeting (IEDM) 2018
DOI: 10.1109/iedm.2018.8614551
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ECRAM as Scalable Synaptic Cell for High-Speed, Low-Power Neuromorphic Computing

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Cited by 143 publications
(155 citation statements)
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“…[108][109][110][111] In addition, electrochemical random-access memory (ECRAM) based on ion intercalation has recently been reported as a promising synaptic cell, showing multi-states and incremental switching with near-ideal switching symmetry and linearity. [29,[112][113][114][115][116][117][118][119] The electrochemically driven ion intercalation process is more controllable than filament-related ion movements in RRAM; therefore, ECRAM also exhibits a much smaller stochasticity. In addition, by borrowing the battery concept, those devices successfully decouple the read and write operations and thus realize low programming energy and long retention time simultaneously.…”
Section: Artificial Synapsesmentioning
confidence: 99%
“…[108][109][110][111] In addition, electrochemical random-access memory (ECRAM) based on ion intercalation has recently been reported as a promising synaptic cell, showing multi-states and incremental switching with near-ideal switching symmetry and linearity. [29,[112][113][114][115][116][117][118][119] The electrochemically driven ion intercalation process is more controllable than filament-related ion movements in RRAM; therefore, ECRAM also exhibits a much smaller stochasticity. In addition, by borrowing the battery concept, those devices successfully decouple the read and write operations and thus realize low programming energy and long retention time simultaneously.…”
Section: Artificial Synapsesmentioning
confidence: 99%
“…Its operation relies on the intercalation/de-intercalation of ions in a channel layer to tune the device conductance. As reported in [108], the intercalation of Li + ions into the WO 3 layer by application of a positive voltage at the gate terminal leads the device to experience a conductance increase whereas the de-intercalation of Li + ions under negative bias leads the device to experience a conductance decrease. The linear conductance change is achievable in ECRAM thanks to the decoupling of read/write paths, which makes this device concept very attractive for synaptic applications, mainly for hardware implementation of synaptic weights in ANNs, where analog and symmetric weight updates play a crucial role.…”
Section: Memristive Devices With Three-terminal Structurementioning
confidence: 72%
“…In addition to the two-terminal devices, memristive concepts also include the class of three-terminal devices whose main examples are those depicted in Figure 12, namely (a) the ferroelectric field-effect transistor (FeFET) [107], (b) the electro-chemical random access memory (ECRAM) [108], and (c) the spin-orbit torque magnetic random access memory (SOT-MRAM) [109]. Other interesting three-terminal concepts that have been recently investigated for neuromorphic computing applications are the 2D semiconductor-based mem-transistors [110,111] and the domain-wall-based magnetic memories [112,113].…”
Section: Memristive Devices With Three-terminal Structurementioning
confidence: 99%
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