论文标题
一个纳米HFO $ _2 $ $基于硅的铁电隧道连接处
One nanometer HfO$_2$-based ferroelectric tunnel junctions on silicon
论文作者
论文摘要
在铁电材料中,自发对称性破坏会导致可切换的电化极化,这为非挥发性记忆提供了重要的希望。特别是,铁电隧道连接(FTJ)已成为一种新的电阻开关存储器,该记忆在薄薄的铁电屏障上利用了偏振依赖性隧道电流。在这里,我们演示了具有CMOS兼容ZR的HFO $ _2 $(ZR:HFO $ _2 $)的FTJ,仅厚度为1 nm的铁电势屏障,由硅的原子层沉积生长。这些1 nm Zr:HFO $ _2 $隧道连接处具有较大的极化驱动的电动(19000 $ \%$),这是HFO $ _2 $ _2 $的FTJ的最大价值。此外,由于仅1 nm的铁电势屏障,这些连接处在低读取电压下提供大型隧道电流(> 1 A/cm $^2 $),比报告的较厚的HFO $ _2 $ _2 $ _2 $ _2 $ _2 $ _2 $ _2 $ _2 $ _2 $ _2 $ _2 $。因此,我们的原则证明提供了一种方法,可以同时克服原型FTJ的三个主要缺点:SI兼容的超薄铁素铁,大电器和大读电流用于高速操作。
In ferroelectric materials, spontaneous symmetry breaking leads to a switchable electric polarization, which offers significant promise for nonvolatile memories. In particular, ferroelectric tunnel junctions (FTJs) have emerged as a new resistive switching memory which exploit polarization-dependent tunnel current across a thin ferroelectric barrier. Here we demonstrate FTJs with CMOS-compatible Zr-doped HfO$_2$ (Zr:HfO$_2$) ferroelectric barriers of just 1 nm thickness, grown by atomic layer deposition on silicon. These 1 nm Zr:HfO$_2$ tunnel junctions exhibit large polarization-driven electroresistance (19000$\%$), the largest value reported for HfO$_2$-based FTJs. In addition, due to just a 1 nm ferroelectric barrier, these junctions provide large tunnel current (> 1 A/cm$^2$) at low read voltage, orders of magnitude larger than reported thicker HfO$_2$-based FTJs. Therefore, our proof-of-principle demonstration provides an approach to simultaneously overcome three major drawbacks of prototypical FTJs: a Si-compatible ultrathin ferroelectric, large electroresistance, and large read current for high-speed operation.
