Developing a conductive oxygen barrier for ferroelectric integration

For high-density FeRAM memories, the 1T–1C architecture has been proposed. In this scheme, the ferrocapacitor (FeCAP), a metal\ferroelectric film\metal-like sandwich, is placed directly on top of polysilicon or tungsten plugs contacted to the underlying CMOS technology. Our ferroelectric material of choice, SrBi₂Ta₂O₉ (SBT), requires crystallization anneals ranging from 650 to 800 °C in full oxygen. The bottom electrode (BE) needs to be conductive, as well as an oxygen barrier to protect the underlying plug from oxidation. We have developed a BE stack combination consisting of Pt/IrO₂/Ir/Ti(Al)N. Each layer plays a critical role in the performance of the barrier. Issues such as thermal expansion, stress relaxation, grain growth, and oxidation can be critical in order to have a working bottom electrode. For capacitor formation, the complete stack is etched and covered by SBT. Since all layers are in contact with SBT, it is important to understand how the ferroelectric interacts with both the individual layers and the combined structure. In this paper, we will present our understanding of the chemical reactivity between SBT and the BE stack, which has been successfully engineered to prevent oxidation of the underlying plug.