Chien-Lung Liang, Yung-Sheng Lin, C. Kao, D. Tarng, Shan-Bo Wang, Y. Hung, Kwang-Lung Lin
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The Cu RDL was stressed with a direct current with 53 mA (8.8 × 105 A/cm2) at 180°C in accordance with the JEDEC standard. After the thermal annealing pre-treatment at 230°C for 6 h, a porous Cu oxide layer accompanying a few nanovoids was formed on top of the Cu RDL. The electromigration test was found to accelerate the oxidation behavior and voiding issue with increasing current stressing time. A bilayer Cu oxide structure was formed upon electromigration, while the nanovoids formed at the oxide/RDL interface increased in number and enlarged in dimension. Large voids formed underneath the Cu RDL, at the Cu RDL/Ti adhesion layer interface, were also observed. These phenomena were responsible for the steady resistance increase under the electromigration test. Once the Cu RDL has been occupied with voids formed upon electromigration, the rapid reduction in the cross-sectional area will give rise to current crowding and thus induce an increasing RDL temperature. The abruptly rising temperature caused the local melting of the Cu RDL and disruption of the neighboring multilayers. The open circuit failure that occurred in the middle region of the Cu RDL, whereas not in the cathode region, suggests a prominent thermal effect induced failure mechanism under the electromigration test.","PeriodicalId":6722,"journal":{"name":"2020 IEEE 70th Electronic Components and Technology Conference (ECTC)","volume":"30 1","pages":"361-366"},"PeriodicalIF":0.0000,"publicationDate":"2020-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"8","resultStr":"{\"title\":\"Electromigration Failure Study of a Fine-pitch 2μm/2μm L/S Cu Redistribution Line Embedded in Polyimide for Advanced High-density Fan-out Packaging\",\"authors\":\"Chien-Lung Liang, Yung-Sheng Lin, C. Kao, D. Tarng, Shan-Bo Wang, Y. 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引用次数: 8
摘要
先进扇出(FO)封装中的Cu再分配线(RDL)接近1-2 μ m甚至亚微米尺度的特征尺寸,以实现高密度(输入/输出(I/O)数> 1000)封装要求。Cu RDL的小型化趋势导致电流密度增加,在2 μ m/2 μ m线/空间(L/S)走线中电流密度将大于105 A/cm2。电热耦合效应引起的电迁移可靠性问题也随之引起关注。研究了长20 μm、厚3 μm、细间距2μm/2μm L/S Cu RDL嵌入聚酰亚胺(PI)介质层中用于高级高密度FO封装的电迁移失效行为和机制。根据JEDEC标准,在180°C下对Cu RDL施加53 mA (8.8 × 105 a /cm2)的直流电流。在230℃下热处理6 h后,在Cu RDL表面形成了一层多孔的氧化铜层,并伴有少量纳米孔。电迁移试验发现,随着电流应力时间的增加,氧化行为和空化问题加速。电迁移形成双层Cu氧化物结构,在氧化物/RDL界面处形成的纳米空洞数量增加,尺寸增大。在Cu RDL下方,Cu RDL/Ti粘附层界面处,形成了较大的孔洞。这些现象是导致电迁移试验中电阻稳定增加的原因。一旦Cu RDL被电迁移形成的空隙占据,横截面积的迅速减小将引起电流拥挤,从而引起RDL温度的升高。温度的突然升高导致Cu RDL的局部熔化和相邻多层的破坏。开路失效发生在Cu RDL的中间区域,而不发生在阴极区域,这表明在电迁移试验中,热效应诱发了明显的失效机制。
Electromigration Failure Study of a Fine-pitch 2μm/2μm L/S Cu Redistribution Line Embedded in Polyimide for Advanced High-density Fan-out Packaging
The Cu redistribution line (RDL) in advanced fan-out (FO) packages is approaching 1-2 µm or even a submicron-scale feature size for achieving high-density (input/output (I/O) number > 1000) packaging requirements. The downsizing trend of the Cu RDL gives rise to an increasing current density which will be greater than 105 A/cm2 in a 2µm/2µm line/space (L/S) trace. The electromigration reliability concerns caused by the electrical-thermal coupling effects may be raised accordingly. The present study reported the electromigration failure behavior and mechanism of a fine-pitch 2μm/2μm L/S Cu RDL, 20 μm in length and 3 μm in thickness, embedded in polyimide (PI) dielectric layer for advanced high-density FO packaging. The Cu RDL was stressed with a direct current with 53 mA (8.8 × 105 A/cm2) at 180°C in accordance with the JEDEC standard. After the thermal annealing pre-treatment at 230°C for 6 h, a porous Cu oxide layer accompanying a few nanovoids was formed on top of the Cu RDL. The electromigration test was found to accelerate the oxidation behavior and voiding issue with increasing current stressing time. A bilayer Cu oxide structure was formed upon electromigration, while the nanovoids formed at the oxide/RDL interface increased in number and enlarged in dimension. Large voids formed underneath the Cu RDL, at the Cu RDL/Ti adhesion layer interface, were also observed. These phenomena were responsible for the steady resistance increase under the electromigration test. Once the Cu RDL has been occupied with voids formed upon electromigration, the rapid reduction in the cross-sectional area will give rise to current crowding and thus induce an increasing RDL temperature. The abruptly rising temperature caused the local melting of the Cu RDL and disruption of the neighboring multilayers. The open circuit failure that occurred in the middle region of the Cu RDL, whereas not in the cathode region, suggests a prominent thermal effect induced failure mechanism under the electromigration test.
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