Temperature Dependence of Volatile Current shoot-up in PrMnO3 based Selector-less RRAM

PrMnO3 (PMO) based Resistance Random Access Memory (RRAM) has recently been considered for selector-less RRAM and neuromorphic computing applications by utilizing its current shoot-up. This current shoot-up in the PMO device is attributed to the thermal runaway in the device. Hence, the understanding of the ambient temperature dependence on the current shoot-up of the PMO device is essential for the various applications that utilize the negative differential resistance (NDR). In this paper, we characterize the ambient thermal dependence of dc IV, accompanied by the development of analytical modeling. First, the temperature-dependent current-voltage characteristic and shift in the threshold voltage of the PMO device are shown experimentally. Second, a Joule heating based thermal feedback model coupled with current transport by space charge limited current (SCLC) is developed to explain the experimentally observed NDR region. Finally, the model successfully predicts device behavior over a range of experimental ambient temperatures. As an alternative to TCAD, such a compact and accurate dc model sets up a platform to enable understanding, design with device and systems-level simulations of memory and neuromorphic applications.