Package structural integrity analysis considering moisture

Fan, Xuejun; Zhou, Jiang; Chandra, Abhijit

doi:10.1109/ectc.2008.4550106

Cited by 12 publications

(2 citation statements)

References 29 publications

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“…The constrains can be expressed in two non-dimensional parameters, i.e. the Dunders' parameters [13], which are [1] Where, the are shear moduli; is defined for plane strain and is for plain stress; denote the material 1 and 2. The other bi-material constants related to Dundurs' parameters are defined as [2] Where is the plane stress tensile modulus and is for the plane strain case; is the oscillatory index for the stress filed near crack tip.…”

Section: The Interface Fracture and Mode Mixitymentioning

confidence: 99%

“…The integrity of the interfaces between different materials becomes challenge when the device is subjected to thermal and mechanical loading. For example, the reliability of devices will be heavily dependent on the behaviors of the interfaces during the high temperature assembly processor being used in variant environments [1]. On the other hand, the interfaces between different materials are hard to control and become weak when small defects were introduced during fabrication process.…”

Section: Introductionmentioning

confidence: 99%

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Study The Mixed-Mode Delamination of The Epoxy/Cu Interface

Liu

Wang

2011

ECS Trans.

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The high density packaging, e.g. stacked die packages et al., includes interfaces between different materials. The device reliability is heavily related to the behavior of the interfaces. For instance, the delamination may propagate along dissimilar material interfaces and lead to electrical failure during the package manufacturing, testing processes and even in working state under severe environmental conditions. The interfaces between the epoxy-based composites and copper may be critical due to the large CTE mismatch of the materials. The interface fracture exhibits mixed-mode that combined with mode-I and model-II fractures. In this work, we designed the sandwich samples and a new apparatus to characterize the interface fracture of the epoxy/Cu interface. The sample can be loaded in different angles. The energy release rate and mode mixity were obtained upon the experimental results by the mixed-mode elastic fracture analysis. The method can be applied for other interface characterization in the packaging.

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Section: The Interface Fracture and Mode Mixitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Study The Mixed-Mode Delamination of The Epoxy/Cu Interface

Liu

Wang

2011

ECS Trans.

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Transient analysis on hygroscopic swelling characterization using sequentially coupled moisture diffusion and hygroscopic stress modeling method

Zhou

2008

Microelectronics Reliability

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A new method for equivalent acceleration of JEDEC moisture sensitivity levels

Shi

Fan

Xie

2008

2008 58th Electronic Components and Technology Conference

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In order to devise an equivalent accelerated moisture sensitivity test, the JEDEC specification J-STD-020C has recommended an accelerated preconditioning time of 40hrs exposure under 60°C/60%RH, which is considered equivalent to the standard moisture sensitivity level 3 (MSL-3) of 216hrs soak time under 30°C/60%RH. However, the existing methodology for the accelerated moisture sensitivity test was developed based on the equivalency of local moisture concentration at the interest of location for leaded packages only. The failure mechanism is restricted to the potential delamination between mold compound and leadframe. In addition, such an equivalency requires the activation energy of molding compound for moisture diffusion in the range of 0.4-0.48eV. This paper introduces a new method to accelerate JEDEC/IPC moisture sensitivity level testing. The methodology is developed based on the equivalency of both local moisture concentration and overall moisture distribution of packages. The local moisture concentration equivalency ensures identical adhesion strength and vapor pressure at interfaces of the interest, and the overall moisture distribution equivalency results in the same condition of applied driving forces, such as thermal and hygroscopic stresses, during reflow. In our previous study [1], this methodology was applied to a molded matrix array package, and an accelerated soak time subjected to 60°C/60%RH was established. In this paper, the further reduction of soak time using 85°C/60%RH is investigated. An ultra-thin stacked-die chip scale package (CSP) is used as the test vehicle. Extensive experiments have been carried out to obtain the failure rate as function of soak time under various environmental conditions. Finite element analysis was performed to obtain the equivalency conditions. According to finite element modeling results, it has been found that, at 70hrs under 60°C/60%RH and 45hrs under 85°C/60%RH, respectively, both the local moisture concentration at critical interface and overall moisture distribution of package become identical to that under the standard MSL-3. Such an equivalency of the new accelerated test conditions has been proven by the test results. Failure site and failure mode indicates that the proposed accelerated tests are well correlated with the standard MSL-3. The new methodology can be extended to other packages.

show abstract

Package structural integrity analysis considering moisture

Cited by 12 publications

References 29 publications

Study The Mixed-Mode Delamination of The Epoxy/Cu Interface

Study The Mixed-Mode Delamination of The Epoxy/Cu Interface

Transient analysis on hygroscopic swelling characterization using sequentially coupled moisture diffusion and hygroscopic stress modeling method

A new method for equivalent acceleration of JEDEC moisture sensitivity levels

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