Interface engineering of oxidized Mo electrodes for imprint stability and enhanced endurance in hafnia-based ferroelectric devices
- Authors
- Hwang, Junghyeon; Kim, Chaeheon; Kang, Geonhyeong; Kim, Yongsu; Ahn, Jinho; Jeon, Sanghun
- Issue Date
- Dec-2025
- Publisher
- ROYAL SOC CHEMISTRY
- Citation
- JOURNAL OF MATERIALS CHEMISTRY C, v.13, no.47, pp 23570 - 23576
- Pages
- 7
- Indexed
- SCIE
SCOPUS
- Journal Title
- JOURNAL OF MATERIALS CHEMISTRY C
- Volume
- 13
- Number
- 47
- Start Page
- 23570
- End Page
- 23576
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/212138
- DOI
- 10.1039/d5tc02605a
- ISSN
- 2050-7526
2050-7534
- Abstract
- Engineering stable electrode interfaces is crucial for achieving reliable hafnia-based ferroelectric devices for next-generation nonvolatile memory applications. In particular, imprint—a bias-induced shift of the polarization–electric field (P–E) hysteresis—can severely impact device stability. Here, we systematically compare tantalum nitride (TaN) and oxidized molybdenum (MoOx) bottom electrodes with MoOx-rich surfaces in metal–ferroelectric–metal capacitors to elucidate the role of interface electronic structures and work function in modulating imprint behavior, endurance, and tunneling performance. Ultraviolet photoelectron spectroscopy (UPS) and X-ray photoelectron spectroscopy (XPS) analyses reveal that short-time high-temperature oxidation of Mo produces Mo6+-rich surfaces with work functions exceeding 5.5 eV, significantly suppressing charge trapping and oxygen vacancy migration at the HZO interface. Capacitors with MoOx-rich electrodes maintain stable imprint voltages and remanent polarization over 106 switching cycles, while TaN-based devices exhibit significant imprint evolution and polarization degradation. Interface trap density measurements confirm that oxidized Mo electrodes achieve a nearly 55% reduction in trap formation compared to TaN counterparts after extended cycling. Furthermore, in ferroelectric tunnel junctions (FTJs), MoOx-rich electrodes enable stable diode-like behavior, high tunneling electroresistance (TER), and robust endurance with minimal degradation up to 107 cycles. These results demonstrate that oxidized Mo electrodes with MoOx-rich surfaces provide chemically stable, high-work-function interfaces that effectively mitigate degradation mechanisms, offering a robust strategy for enhancing the performance, reliability, and scalability of ferroelectric memory and logic devices.
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