Abstract
The insertion of a metal layer between an active electrode and a switching layer leads to the formation of a ternary oxide at the interface. The properties of this self-formed oxide are found to be dependent on the Gibbs free energy of oxide formation of the metal (ΔGf°). We investigated the role of various ternary oxides in the switching behavior of conductive bridge random access memory (CBRAM) devices. The ternary oxide acts as a barrier layer that can limit the mobility of metal cations in the cell, promoting stable switching. However, too low (higher negative value) ΔGf° leads to severe trade-offs; the devices require high operation current and voltages to exhibit switching behavior and low memory window (on/off) ratio. We propose that choosing a metal layer having appropriate ΔGf° is crucial in achieving reliable CBRAM devices.
Highlights
Hnology utilizes the ionization of metal electrode atoms (Ag, Cu, Ni, or Te cations) to create a conducting bridge.8 The mobility of cations is higher than that of anions due to their smaller ionic size; conductive bridge random access memory (CBRAM) technology could offer a faster switching speed than OxRAM.10
We investigated the role of various ternary oxides in the switching behavior of conductive bridge random access memory (CBRAM) devices
The ternary oxide acts as a barrier layer that can limit the mobility of metal cations in the cell, promoting stable switching
Summary
Hnology utilizes the ionization of metal electrode atoms (Ag, Cu, Ni, or Te cations) to create a conducting bridge.8 The mobility of cations is higher than that of anions due to their smaller ionic size; CBRAM technology could offer a faster switching speed than OxRAM.10.
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