Nano- und micro sized filler particles for improved humidity resistance of encapsulants

Author

Braun, T. ; Bauer, J. ; Georgi, L. ; Becker, K.-F. ; Koch, M. ; Thomas, T. ; Bader, V. ; Aschenbrenner, R. ; Reichl, H.

Author_Institution

Fraunhofer Inst. for Reliability & Microintegration, Berlin, Germany

fYear

2010

fDate

Feb. 28 2010-March 2 2010

Firstpage

22

Lastpage

28

Abstract

This paper describes the potential of different nano- and micro-sized particles as additives for plastic packaging materials for enhanced humidity resistance/barrier enhancement within microelectronic packages as well testing methods for material characterization concerning their humidity diffusion and absorption properties. This topic is gaining increased importance when considering the trend towards System in Package, where a multitude of components is encapsulated to form one miniaturized SiP that incorporates a large number of different material interfaces and interconnects. These SiPs need to be protected from the environment by encapsulants layers with ever decreasing thickness and thus increased moisture barrier properties.

Keywords

absorption; electronics packaging; humidity; plastic packaging; system-in-package; absorption property; barrier enhancement; encapsulants; humidity diffusion property; humidity resistance; material characterization; micro sized filler particle; microelectronic package; nano-sized filler particle; plastic packaging material; system in package; testing method; Assembly; Environmentally friendly manufacturing techniques; Epoxy resins; Humidity; Lead; Materials reliability; Microelectronics; Moisture; Plastic packaging; Polymers;

fLanguage

English

Publisher

ieee

Conference_Titel

Advanced Packaging Materials: Microtech, 2010. APM '10. International Symposium on

Conference_Location

Cambridge

Print_ISBN

978-1-4244-6756-3

Type

conf

DOI

10.1109/ISAPM.2010.5441384

Filename

5441384