炉内退火的hfo2薄膜用于将铁电功能整合到BEoL中

D. Lehninger, T. Ali, R. Olivo, M. Lederer, T. Kämpfe, K. Mertens, K. Seidel
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引用次数: 7

摘要

在掺杂氧化铪薄膜中发现铁电性导致了铁电记忆概念的复兴。与所有被检测的掺杂剂相比,锆掺杂的氧化铪(HZO)在最低的温度下结晶。因此,这种材料系统是理想的实现有限元功能到后端线(BEoL)。到目前为止,FE相是通过快速热退火(RTA)来实现的。最近,研究表明,在400°C的单炉退火足以使薄膜功能化。本文比较了各种退火条件,以进一步减少热预算和工艺步骤。结果表明,在300℃下热处理1 h, HZO薄膜在FE相中结晶。在结晶度方面,与400°C退火的薄膜相比,这些薄膜没有明显的退化。然而,残余极化随温度的升高略有降低,但在300℃时仍然足够。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Furnace annealed HfO2-Films for the Integration of Ferroelectric Functionalities into the BEoL
The discovery of ferroelectricity in thin films of doped hafnium oxide has led to a renaissance of ferroelectric (FE) memory concepts. Compared to all inspected dopants, zirconium doped hafnium oxide (HZO) crystallizes at the lowest temperatures. Thus, this material system is ideal for the implementation of FE functionalities into the back-end-of-line (BEoL). So far, the FE phase is achieved by rapid thermal annealing (RTA) of prior amorphous HZO films. Recently, it was shown that a sole furnace anneal at 400°C is sufficient to functionalize the films. Herein, a wide range of annealing conditions are compared in order to further reduce the thermal budget and the number of process steps. It is found that furnace-annealing at 300°C for 1 h crystallizes the HZO films in the FE phase. With respect to crystallinity, these films show no significant degradation compared to films annealed at 400°C. Nevertheless, the remanent polarization reduces slightly with temperature, but is still sufficient even at 300°C.
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