Protonation-Driven Polarization Retention Failure in Nano-Columnar Lead-Free Ferroelectric Thin Films
- Authors
- Sheeraz, Muhammad; Ahn, Chang Won; Duong, Nguyen Xuan; Hwang, SooYoon; Jang, JiSoo; Kim, EunYoung; Kim, Yoon Ki; Lee, Jaeyeong; Jin, Jong Sung; Bae, JongSeong; Lee, Myang Hwan; Han, HyoungSu; Kim, GiYeop; Cho, Shinuk; Song, Tae Kwon; Yang, Sang Mo; Bu, Sang Don; Baek, SeungHyub; Choi, SiYoung; Kim, Ill Won; Kim, Tae Heon
- Issue Date
- 2024-11
- Publisher
- Wiley-VCH Verlag
- Citation
- Advanced Science
- Abstract
- Understanding microscopic mechanisms of polarization retention characteristics in ferroelectric thin films is of great significance for exploring unusual physical phenomena inaccessible in the bulk counterparts and for realizing thin-film-based functional electronic devices. Perovskite (K,Na)NbO3 is an excellent class of lead-free ferroelectric oxides attracting tremendous interest thanks to its potential applications to nonvolatile memory and eco-friendly energy harvester/storage. Nonetheless, in-depth investigation of ferroelectric properties of (K,Na)NbO3 films and the following developments of nano-devices are limited due to challenging thin-film fabrication associated with nonstoichiometry by volatile K and Na atoms. Herein, ferroelectric (K,Na)NbO3 films of which the atomic-level geometrical structures strongly depend on thickness-dependent strain relaxation are epitaxially grown. Nanopillar crystal structures are identified in fully relaxed (K,Na)NbO3 films to the bulk states representing a continuous reduction of switchable polarization under air environments, that is, polarization retention failures. Protonation by water dissociation is responsible for the humidity-induced retention loss in nano-columnar (K,Na)NbO3 films. The protonation-driven polarization retention failure originates from domain wall pinning by the accumulation of mobile hydrogen ions at charged domain walls for effective screening of polarization-bound charges. Conceptually, the results will be utilized for rational design to advanced energy materials such as photo-catalysts enabling ferroelectric tuning of water splitting.
- Keywords
- ferroelectric; (K,Na)NbO3; thin film; polarization retention loss; epitaxy
- URI
- https://pubs.kist.re.kr/handle/201004/151060
- DOI
- 10.1002/advs.202408784
- Appears in Collections:
- KIST Article > 2024
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