Designing wake-up free ferroelectric capacitors based on the HfO2/ZrO2 superlattice structure

Abstract

The wake-up phenomenon widely exists in hafnia-based ferroelectric capacitors, which causes device parameter variation over time. Crystallization at higher temperatures have been reported to be effective in eliminating wake-up, but high temperature may yield the monoclinic phase or generate high concentration oxygen vacancies. In this work, a unidirectional annealing method is proposed for the crystallization of Hf0.5Zr0.5O2 (HZO) superlattice ferroelectrics, which involves heating from the Pt/ZrO2 interface side. Nanoscale ZrO2 is selected to resist the formation of monoclinic phase, and the chemically inert Pt electrode can avoid the continuous generation of oxygen vacancies during annealing. It is demonstrated that 600oC annealing only leads to a moderate content of monoclinic phase in HZO, and the TiN/HZO/Pt capacitor exhibits wake-up free nature and a 2Pr value of 27.4 μC/cm2. On the other hand, heating from the TiN/HfO2 side, or using 500oC annealing temperature, both yield ferroelectric devices that require a wake-up process. The special configuration of Pt/ZrO2 is verified by comparative studies with several other superlattice structures and HZO solid-state solutions. It is discovered that heating from the Pt/HfO2 side at 600oC leads to high leakage current and a memristor behavior. The mechanisms of ferroelectric phase stabilization and memristor formation have been discussed. The unidirectional heating method can also be useful for other hafnia-based ferroelectric devices.