Magnetic alignment technology for wafer bonding

IF 0.7 4区工程技术 Q4 ENGINEERING, ELECTRICAL & ELECTRONIC Microelectronics International Pub Date : 2023-04-20 DOI:10.1108/mi-08-2022-0160

L. Ye, Xuanjie Song, Chang Yue

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Abstract

Purpose Wafer bonding is a key process for 3 D advanced packaging of integrated circuits. It requires very high accuracy for the wafer alignment. To solve the problems of large movement stroke, position calibration error and low production efficiency in optical alignment, this paper aims to propose a new wafer magnetic alignment technology (MAT) which is based on tunnel magneto resistance effect. MAT can realize micro distance alignment and reduces the design and manufacturing difficulty of wafer bonding equipment. Design/methodology/approach The current methods and existing problems of wafer optical alignment are introduced, and the mechanism and realization process of wafer magnetic alignment are proposed. Micro magnetic column (MMC) marks are designed on the wafer by the semiconductor manufacturing process. The mathematical model of the space magnetic field of the MMC is established, and the magnetic field distribution of the MMC alignment is numerically simulated and visualized. The relationship between the alignment accuracy and the MMC diameter, MMC remanence, MMC thickness and sensor measurement height was studied. Findings The simulation analysis shows that the overlapping double MMCs can align the wafer with accuracy within 1 µm and can control the bonding distance within the micrometer range to improve the alignment efficiency. Originality/value Magnetic alignment technology provides a new idea for wafer bonding alignment, which is expected to improve the accuracy and efficiency of wafer bonding.

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用于晶片键合的磁对准技术

目的晶圆键合是3 D集成电路的高级封装。它对晶片对准要求非常高的精度。为了解决光学对准中移动行程大、位置校准误差大、生产效率低的问题，本文提出了一种基于隧道磁阻效应的新型晶圆磁对准技术。MAT可以实现微距离对准，降低了晶圆键合设备的设计和制造难度。设计/方法/途径介绍了目前晶圆光学对准的方法和存在的问题，提出了晶圆磁对准的机理和实现过程。微磁柱（MMC）标记是通过半导体制造工艺在晶片上设计的。建立了MMC空间磁场的数学模型，对MMC排列的磁场分布进行了数值模拟和可视化。研究了对准精度与MMC直径、MMC剩磁、MMC厚度和传感器测量高度之间的关系。仿真分析表明，重叠的双MMC可以在1 µm，并且可以将接合距离控制在微米范围内，以提高对准效率。独创性/价值磁对准技术为晶圆接合对准提供了一种新的思路，有望提高晶圆接合的精度和效率。

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来源期刊

Microelectronics International 工程技术-材料科学：综合

CiteScore

1.90

自引率

9.10%

发文量

审稿时长

>12 weeks

期刊介绍： Microelectronics International provides an authoritative, international and independent forum for the critical evaluation and dissemination of research and development, applications, processes and current practices relating to advanced packaging, micro-circuit engineering, interconnection, semiconductor technology and systems engineering. It represents a current, comprehensive and practical information tool. The Editor, Dr John Atkinson, welcomes contributions to the journal including technical papers, research papers, case studies and review papers for publication. Please view the Author Guidelines for further details. Microelectronics International comprises a multi-disciplinary study of the key technologies and related issues associated with the design, manufacture, assembly and various applications of miniaturized electronic devices and advanced packages. Among the broad range of topics covered are: • Advanced packaging • Ceramics • Chip attachment • Chip on board (COB) • Chip scale packaging • Flexible substrates • MEMS • Micro-circuit technology • Microelectronic materials • Multichip modules (MCMs) • Organic/polymer electronics • Printed electronics • Semiconductor technology • Solid state sensors • Thermal management • Thick/thin film technology • Wafer scale processing.