Hafnia-based ferroelectrics (FEs) can be stabilized via careful engineering, both kinetically and thermodynamically. Especially, the fast cooling process has been regarded as an efficient approach for kinetically maximizing the phase transition to the orthorhombic (o-) phase from the tetragonal (t-) phase, which stabilizes thermodynamically during crystallization annealing. However, accurately controlling the cooling period for fast cooling procedures is challenging, resulting in unreliable and nonreproducible outcomes and interpretation. Thus, until now, comprehending its effects has mainly relied on modeling efforts in the field of material science. Here, for the first time, we experimentally validate the fast-cooling effect with Al:HfO2 FEs, based on the novel equipment ensuring both reliability and reproducibility. In addition, it enabled us to investigate the impact of the fast cooling process on the phase, domain size, and interface quality of FEs through various electrical analyses. The fast cooling technique facilitates the transition from the t-phase to the desired o-phase, inducing significantly higher remanent polarization values of 2Pr (35.31 µC/cm2) and improved subloop characteristics. In contrast, slow cooling (2Pr of 9.50 µC/cm2) leads to poor subloop properties. Given that a fast cooling procedure is useful for stabilizing the FE o-phase in thin films, we believe that our reliable annealing procedure and significant experimental findings can provide a foundation for future studies in hafnia FE material and memory devices.
This work was supported in part by K-CHIPS (Korea Collaborative and High-tech Initiative for Prospective Semiconductor Research) under Grant 1415187675, Grant 00235655, and Grant 23006-15TC; in part by the Ministry of Trade, Industry and Energy (MOTIE, Korea) under Grant 1415187390, Grant 00231985, and Grant 23005-30FC; and in part by the National Research Foundation of Korea (NRF) grant funded by the Korea Government (Ministry of Science and ICT) under Grant RS-2023-00260527.Received 4 September 2024; accepted 23 September 2024. This work was supported in part by K-CHIPS (Korea Collaborative and High-tech Initiative for Prospective Semiconductor Research) under Grant 1415187675, Grant 00235655, and Grant 23006-15TC; in part by the Ministry of Trade, Industry and Energy (MOTIE, Korea) under Grant 1415187390, Grant 00231985, and Grant 23005-30FC; and in part by the National Research Foundation of Korea (NRF) grant funded by the Korea Government (Ministry of Science and ICT) under Grant RS-2023-00260527. The review of this article was arranged by Editor P.-Y. Du. (Lingwei Zhang and Giuk Kim contributed equally to this work.) (Corresponding authors: Jinho Ahn; Sanghun Jeon.) Lingwei Zhang, Giuk Kim, Sangho Lee, Hunbeom Shin, and Sanghun Jeon are with the School of Electrical Engineering, Korea Advanced Institute of Science and Technology (KAIST), Daejeon 34141, South Korea (e-mail: jeonsh@kaist.ac.kr).
