Embedded-Component Planar Fan-Out Packaging for Biophotonic Applications

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Akeeb Hassan;Sepehr Soroushiani;Abdulhameed Abdal;Sk Yeahia Been Sayeed;Wei-Chiang Lin;Markondeya Raj Pulugurtha
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Abstract

Embedded-chip planar silver-elastomer interconnect technology is developed with flexible substrates and demonstrated for on-skin biophotonic sensor applications. This approach has several benefits and is also consistent with chip-thinning where the chip thickness is 100 microns and less. The key benefits from this approach arise because both the bottom and top sides are now available as flat surfaces for 3D integration of other components. It also results in the lowest electrical parasitics compared to flipchip with adhesives or printed-ramp interconnections with surface-assembled devices. Embedding of chips in flexible carriers was accomplished with direct screen-printed interconnects onto the chip pads in substrate cavities. Silver nanoflake-loaded polyurethane is utilized in the embedded-chip packages to provide the desired lower interconnect resistance and also reliability in flexible packages under deformed configurations. Viscoelastic models were utilized to model the interconnection stresses. Planar interconnects in flexible substrates are developed with conductive silver-loaded elastomer interconnects. This approach is compared to direct chip-on-flex assembly technology for reliability under bending and high-temperature storage. The embedded-chip technology is demonstrated through biophotonic sensor applications where light sources (LEDs) and photodetectors are embedded inside the package. Functional validation in bent configuration at low curvatures is shown by measuring pulse rate and muscle activity with human subjects. By extending this technology to nanowires in elastomers, further enhancement in electrical and reliability performance can be achieved.
生物光子应用的嵌入式元件平面扇出封装
采用柔性衬底开发了嵌入式芯片平面银弹性体互连技术,并演示了其在皮肤上生物光子传感器中的应用。这种方法有几个好处,也符合芯片薄化,芯片厚度为100微米或更少。这种方法的主要好处在于,底部和顶部都可以作为平面,用于其他组件的3D集成。与使用粘合剂的倒装芯片或与表面组装器件的印刷匝道互连相比,它还具有最低的电寄生。在柔性载体中嵌入芯片是通过直接丝网印刷互连到衬底腔中的芯片衬垫上完成的。在嵌入式芯片封装中使用了负载银纳米片的聚氨酯,以提供所需的更低的互连电阻和在变形配置下柔性封装的可靠性。粘弹性模型用于模拟连接应力。采用导电载银弹性体互连开发了柔性衬底中的平面互连。这种方法与直接柔性芯片组装技术相比,在弯曲和高温存储下的可靠性更高。嵌入式芯片技术通过生物光子传感器应用进行了演示,其中光源(led)和光电探测器嵌入到封装中。通过测量人体受试者的脉搏率和肌肉活动,显示了低曲率弯曲配置的功能验证。通过将该技术扩展到弹性体中的纳米线,可以进一步提高电气性能和可靠性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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