Plastic encapsulated devices are of great interest against their ceramic or metallic counterparts, as they permit significant cost reductions. However, they are more sensitive to moisture ingress, which can lead to reliability problems. Moisture can penetrate either through the polymer or along the interface between the leads and the encapsulant. Samples of 3 different polymers usually used for IC’s encapsulation, either pure or containing a lead frame with the lead terminations, were aged under different RH conditions. Results show that the penetration through the polymer is preponderant face to the progression along the leads. In a first approach, this penetration can be considered as a diffusion process, following the Fick’s law; the diffusion coefficient D and the saturation coefficient S can be deduced from the measurements as a function of the relative humidity. These values can be used in finite element simulations, in order to evaluate the moisture ingress as a function of time within an IC of a given geometry. Moisture diffusion within these new resins is a very long process. In fact, a first “saturation” occurs after a few hours of aging, but if samples are left longer in the oven, a new diffusion process occurs, not leading to a real saturation. Hence processes different than pure fickian diffusion occur in the polymers.

1.
McCluskey, P., Munamarty, R., and Pecht, M., 1996, “Popcorning in PBGA packages during IR reflow soldering,” Proc. of the 1996 International Electronic Packaging Conference, pp. 271–281.
2.
Tanaka, N., Kinato, M., Kumazawa, T., and Nishimuri, A., 1997, “Evaluation of interface delamination in IC packages by considering swelling of the molding compound due to moisture absorption,” Proc. of the 1997 Electronic Components and Technology Conference, pp. 78–83.
3.
Shook
,
R. L.
,
Conrad
,
T. R.
,
Sastry
,
V. S.
, and
Steele
,
D. B.
,
1996
, “
Diffusion model to derate sensitive surface mount IC’s for factory use conditions
,”
IEEE Trans. Compon. Packag. Manufact. Technol. Part C
,
19
, No.
2
, pp.
110
118
.
4.
Shook, R. L., Vacaro, B. T., and Gerlach, D. L., 1998, “Method for equivalent acceleration of JEDEC/IPC moisture sensitivity levels,” Proc. of the IRPS.
5.
Wong, E. H., Teo, Y. C.., and Lim, T. B., 1998, “Moisture diffusion and vapor pressure modeling of IC packaging” Proc. of the 1998 Electronic Components and Technology Conference, pp. 1372–1378.
6.
Holalkere, V., Mirano, S., Kuo, A. Y., and Chen, W. T., 1997, “Evaluation of plastic package delamination via reliability testing and fracture mechanism approach,” Proc. of the 1997 Electronic Components and Technology Conference, pp. 430–435.
7.
Crank, J., 1975, The Mathematics of Diffusion, 2nd Ed., Oxford.
8.
Cai
,
L. W.
, and
Weistman
,
Y.
,
1994
, “
Non-Fickian moisture diffusion in polymeric composites
,”
J. Compos. Mater.
,
28
, No.
2
, pp.
130
154
.
9.
Rousseau, C., Lombae¨rt-Valot, I., and Chopin, J. M., 1992, “Evolution of molding material of biased plastic package components aged by hygrothermic cycling,” IEEE/ISHM ’92 Symposium, pp. 100–107.
10.
Wong
,
T. C.
, and
Broutman
,
L. J.
, 1985, “Moisture diffusion in epoxy resins,” Polym. Eng. Sci., Parts 1 and 2, 25, No. 9, June.
You do not currently have access to this content.