Thermodynamic modeling framework with experimental investigation of the large-scale bonded area and local void in Cu-Cu bonding interface for advanced semiconductor packaging

IF 9.4 1区 材料科学 Q1 ENGINEERING, MECHANICAL
Sung-Hyun Oh , Hyun-Dong Lee , Jae-Uk Lee , Sung-Ho Park , Won-Seob Cho , Yong-Jin Park , Alexandra Haag , Soichi Watanabe , Marco Arnold , Hoo-Jeong Lee , Eun-Ho Lee
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Abstract

With the increase in computational costs driven by the use of artificial intelligence, enhancing the performance of semiconductor systems while improving efficiency has become an inevitable challenge. Due to the fine pitch limits of micro bumps, bumpless Cu-Cu bonding is emerging as the next-generation core technology. This study aims to analyze the effects of individual temperature and pressure on both large- and local-scale behaviors of material in the Cu-Cu bonding process with experiments and numerical analysis. The motivation of this study is to compensate the deficiencies in reported studies on process optimization, particularly the lack of exploration of the separated effects of temperature and pressure on large- and local-scale Cu-Cu bonding. Furthermore, reports on the thermodynamic modeling of Cu-Cu bonding behavior are not sufficient, making it challenging to find suitable models. Bonding experiments were performed by independently controlling the temperature and pressure using blank Cu films treated by precise chemical mechanical polishing (CMP) processes. The large-scale bonded area under each condition was measured, and transmission electron microscope (TEM) images were captured to observe the patterns of local void formation under various temperature and pressure conditions. In the experiments, it was observed that the temperature increase had a greater impact on the bonded area at a larger scale than the increase in pressure. However, for nanoscale-local voids, an increase in pressure had a more dominant effect. To discuss the experimental results, a thermodynamic modeling framework that considers coupled heat-induced deformation, plastic deformation, and volumetric changes caused by material flux was proposed. The proposed model has been implemented in the user-defined material subroutine (UMAT) of the ABAQUS program for finite element (FE) analysis. Numerical analysis using the proposed model captures the experimental data well. In large-scale simulations, temperature conditions have a significant impact, with plastic deformation being the primary mode of deformation, while the pressure conditions dominate the material flux, making substantial contributions to reducing voids at local-scale. To achieve complete closure of the void, the simulation demonstrated that maintaining a sufficient pressure gradient until the complete closure is required. The study findings provide an explicit understanding of how the temperature and pressure conditions differently affect large-scale bonding and local voids for semiconductor package manufacturing.

用于先进半导体封装的铜-铜键合界面大尺度键合面积和局部空隙的热力学建模框架与实验研究
随着人工智能的使用导致计算成本的增加,在提高效率的同时增强半导体系统的性能已成为不可避免的挑战。由于微凸块的细间距限制,无缓冲铜-铜键合正成为下一代核心技术。本研究旨在通过实验和数值分析,分析在铜-铜键合过程中,单个温度和压力对材料的大尺度和局部行为的影响。本研究的动机是弥补已报道的工艺优化研究的不足,特别是缺乏对温度和压力对大尺度和局部尺度铜-铜结合的单独影响的探索。此外,有关铜-铜键合行为的热力学建模的报道也不够充分,因此寻找合适的模型具有挑战性。我们利用经过精密化学机械抛光(CMP)工艺处理的空白铜膜,通过独立控制温度和压力进行了键合实验。测量了各种条件下的大尺度键合面积,并拍摄了透射电子显微镜(TEM)图像,以观察不同温度和压力条件下局部空隙形成的模式。在实验中观察到,温度的升高比压力的升高对更大尺度的结合面积影响更大。然而,对于纳米级局部空隙,压力的增加具有更主要的影响。为了讨论实验结果,我们提出了一个热力学建模框架,该框架考虑了热诱导变形、塑性变形和材料通量引起的体积变化。提出的模型已在用于有限元(FE)分析的 ABAQUS 程序的用户自定义材料子程序(UMAT)中实施。使用所提模型进行的数值分析很好地捕捉到了实验数据。在大规模模拟中,温度条件具有重大影响,塑性变形是主要的变形模式,而压力条件则主导材料通量,为减少局部尺度的空隙做出了重大贡献。模拟结果表明,要实现空隙的完全闭合,需要保持足够的压力梯度,直至完全闭合。研究结果使人们明确了解了温度和压力条件如何对半导体封装制造中的大规模粘合和局部空隙产生不同影响。
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来源期刊
International Journal of Plasticity
International Journal of Plasticity 工程技术-材料科学:综合
CiteScore
15.30
自引率
26.50%
发文量
256
审稿时长
46 days
期刊介绍: International Journal of Plasticity aims to present original research encompassing all facets of plastic deformation, damage, and fracture behavior in both isotropic and anisotropic solids. This includes exploring the thermodynamics of plasticity and fracture, continuum theory, and macroscopic as well as microscopic phenomena. Topics of interest span the plastic behavior of single crystals and polycrystalline metals, ceramics, rocks, soils, composites, nanocrystalline and microelectronics materials, shape memory alloys, ferroelectric ceramics, thin films, and polymers. Additionally, the journal covers plasticity aspects of failure and fracture mechanics. Contributions involving significant experimental, numerical, or theoretical advancements that enhance the understanding of the plastic behavior of solids are particularly valued. Papers addressing the modeling of finite nonlinear elastic deformation, bearing similarities to the modeling of plastic deformation, are also welcomed.
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