在 300 °C 下通过原子层沉积在 Ru 上直接生长铁电正交菱形 ZrO2。

IF 12.2 2区 材料科学 Q1 CHEMISTRY, MULTIDISCIPLINARY Materials Horizons Pub Date : 2024-11-05 DOI:10.1039/d4mh01119h
Myeongchan Ko, Ji Su Park, Soyun Joo, Seungbum Hong, Jong Min Yuk, Kyung Min Kim
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引用次数: 0

摘要

萤石结构的二元氧化物铁电体在厚度低于 10 纳米时表现出强大的铁电性,使其具有高度可扩展性,可用于高端半导体器件。尽管前景广阔,但实现高度可靠的铁电仍需要大量的热预算才能形成铁电相,这也是它们在高端互补金属氧化物半导体(CMOS)加工中使用的一个障碍。在这里,我们报告了通过等离子体增强原子层沉积技术在 300 °C 温度下在取向 (002) Ru 上沉积的 8 nm 厚 ZrO2 薄膜的稳健铁电行为,无需任何后退火工艺,证明了与 CMOS 加工的高度兼容性。根据高分辨率透射电子显微镜和压电显微镜的结果,我们认为其合理机制是局部畴匹配外延,即正交 ZrO2 的[101]取向晶粒和 Ru 的[010]取向晶粒之间的模板效应使铁电 ZrO2 得以直接生长。2Pr 值为 20 μC cm-2,在 400 °C 下退火后可进一步提高到 23 μC cm-2,且不会出现唤醒行为。铁电开关显示出高达 109 个周期的稳定耐久性,展示了其在 CMOS 兼容应用和低热预算纳米电子器件中的巨大潜力。
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Direct growth of ferroelectric orthorhombic ZrO2 on Ru by atomic layer deposition at 300 °C.

Fluorite-structured binary oxide ferroelectrics exhibit robust ferroelectricity at a thickness below 10 nm, making them highly scalable and applicable for high-end semiconductor devices. Despite this promising prospect, achieving highly reliable ferroelectrics still demands a significant thermal budget to form a ferroelectric phase, being a hurdle for their use in high-end complementary metal oxide semiconductor (CMOS) processing. Here, we report a robust ferroelectric behavior of an 8 nm-thick ZrO2 film deposited via plasma-enhanced atomic layer deposition at 300 °C on a (002)-oriented Ru without any post-annealing process, demonstrating high compatibility with CMOS processing. We propose that a plausible mechanism for this is the local domain matching epitaxy based on the high-resolution transmission electron microscopy and piezoelectric force microscopy results, where the templating effect between [101]-oriented grains of orthorhombic ZrO2 and [010]-oriented grains of Ru enables the direct growth of ferroelectric ZrO2. The 2Pr value is 20 μC cm-2, and it can be further improved by post-annealing at 400 °C to 23 μC cm-2 without showing the wake-up behavior. Ferroelectric switching shows stable endurance for up to 109 cycles, showcasing its high potential in CMOS-compatible applications and nanoelectronics with a low thermal budget.

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来源期刊
Materials Horizons
Materials Horizons CHEMISTRY, MULTIDISCIPLINARY-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
18.90
自引率
2.30%
发文量
306
审稿时长
1.3 months
期刊介绍: Materials Horizons is a leading journal in materials science that focuses on publishing exceptionally high-quality and innovative research. The journal prioritizes original research that introduces new concepts or ways of thinking, rather than solely reporting technological advancements. However, groundbreaking articles featuring record-breaking material performance may also be published. To be considered for publication, the work must be of significant interest to our community-spanning readership. Starting from 2021, all articles published in Materials Horizons will be indexed in MEDLINE©. The journal publishes various types of articles, including Communications, Reviews, Opinion pieces, Focus articles, and Comments. It serves as a core journal for researchers from academia, government, and industry across all areas of materials research. Materials Horizons is a Transformative Journal and compliant with Plan S. It has an impact factor of 13.3 and is indexed in MEDLINE.
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