The intercell variability of the initial state and the impact of dc and pulse forming on intercell variability as well as on intracell variability in TiN/HfO2/Ti/TiN 1 transistor – 1 resistor (1T-1R) devices in 4-kb memory arrays were investigated. Nearly 78% of devices on particular arrays were dc formed with a wordline (WL) voltage $V_{text {WL}}= 1.4$ V and a bitline (BL) voltage $V_{text {BL}}= 2.3$ V, whereas 22% of devices were not formed due to the combined effect of the extrinsic process-induced intercell variability of the initial state and the intrinsic intercell variability after dc forming. Furthermore, pulse-induced forming with pulsewidths on the order of $10~mu text{s}$ ( $V_{text {WL}}= 1.4$ V and $V_{text {BL}}= 3.5$ V) caused for 86% of devices a low-resistance state. Using a retry algorithm, we achieve 100% of formed devices. To assess and confirm the nature of the variability during forming operation and during cycling, the quantum point-contact model was considered. The modeling results demonstrate a relationship between the forming and the device performance. The cells requiring high energy for the forming operation, due to impurities in the HfO2 deposition during array processing, are those subject to poor switching performance, larger variability, and faster wear out. Devices formed by a pulse-retry algorithm show: 1) shorter endurance and 2) higher variability during cyclin
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