Toward Low-Thermal-Budget Hafnia-Based Ferroelectrics via Atomic Layer Deposition
Jin-Hyun Kim, Jin-Hyun Kim, Takashi Onaya, Hye Ryeon Park, Yong Chan Jung, Dan N. Le, Minjong Lee, Heber Hernandez‐Arriaga, Yugang Zhang, Esther H. R. Tsai, Chang‐Yong Nam, Toshihide Nabatame, Si Joon Kim, Jiyoung Kim, Jiyoung Kim
Abstract
Since the first report of ferroelectricity in fluorite structure oxides a decade ago, significant attention has been devoted to studying hafnia-based ferroelectric material systems due to their promising properties and opportunities. To achieve such ferroelectric fluorite structure oxides at low temperatures (below 400 °C), stabilizing the metastable noncentrosymmetric orthorhombic phase is crucial. This review provides a comprehensive overview of atomic layer deposition (ALD) techniques for obtaining the orthorhombic phase for low-temperature ferroelectric applications. We discuss optimization of the ALD process for synthesizing high-quality, low-temperature crystallizing ferroelectric films, including doping, precursor and oxygen source selection, deposition temperature, and interface engineering. In addition, the techniques for stabilizing the ferroelectric phase by regulating the thermal budget and stress with various annealing methods and stressors are discussed. The review focuses on different techniques to reduce the thermal budget required to acquire ferroelectricity, making hafnia-based ferroelectric materials compatible with back-end-of-line and three-dimensional integration for a variety of future applications, including flexible electronics applications.