The Woodruff School

SUMMARY

It is projected by the Semiconductor Industry Association in their International Technology Roadmap for Semiconductors (ITRS) that by the year 2019, with the IC feature size shrinking to about 10nm, off-chip interconnects in an area array format will require a pitch of 95um. Also, as the industry adopts porous low-K dielectric materials, it is important to ensure that the stresses induced by the off-chip interconnects and the package do not crack or delaminate the low-K material. Compliant free-standing structures used as off-chip interconnects are a potential solution. However, there are several design, fabrication, assembly and integration research challenges and gaps with the current suite of compliant interconnects. Accordingly, as part of this research a unique parallel-path approach has been developed which enhances the mechanical compliance of the compliant interconnect without compromising the electrical parasitics. It also provides for redundancy and thus results in more reliable interconnects. Also, to meet both electrical and mechanical performance needs, as part of this research a variable compliance approach has been developed so that interconnects near the center of the die have lower electrical parasitics while the interconnects near the corner of the die have higher mechanical compliance. Furthermore, this work has developed a fabrication process which will facilitate cost-effective fabrication of free-standing compliant interconnects and investigated key factors which impact assembly yield of free-standing compliant interconnects. Ultimately the proposed approaches are demonstrated by developing an innovative compliant interconnect called FlexConnects. Hence, through this research it is expected that the developed compliant interconnect would address the needs of first level interconnects over the next decade and eliminate a bottleneck that threatens to impede the exponential growth in microprocessor performance. Also, the concepts developed in this research are generic in nature and can be extended to other aspects of electronic packaging.

SUBJECT:	Ph.D. Dissertation Defense

BY:	Karan Kacker

TIME:	Monday, July 28, 2008, 10:00 a.m.

PLACE:	MARC Building, 401

TITLE:	Design and Fabrication of Free-Standing Structures as Off-Chip Interconnects for Microsystems Packaging

COMMITTEE:	Dr. Suresh Sitaraman, Chair (ME) Dr. Nazanin Bassiri-Gharb (ME) Dr. F. Levent Degertekin (ME) Dr. John Papapolymerou (ECE) Dr. Madhavan Swaminathan (ECE)

SUMMARY It is projected by the Semiconductor Industry Association in their International Technology Roadmap for Semiconductors (ITRS) that by the year 2019, with the IC feature size shrinking to about 10nm, off-chip interconnects in an area array format will require a pitch of 95um. Also, as the industry adopts porous low-K dielectric materials, it is important to ensure that the stresses induced by the off-chip interconnects and the package do not crack or delaminate the low-K material. Compliant free-standing structures used as off-chip interconnects are a potential solution. However, there are several design, fabrication, assembly and integration research challenges and gaps with the current suite of compliant interconnects. Accordingly, as part of this research a unique parallel-path approach has been developed which enhances the mechanical compliance of the compliant interconnect without compromising the electrical parasitics. It also provides for redundancy and thus results in more reliable interconnects. Also, to meet both electrical and mechanical performance needs, as part of this research a variable compliance approach has been developed so that interconnects near the center of the die have lower electrical parasitics while the interconnects near the corner of the die have higher mechanical compliance. Furthermore, this work has developed a fabrication process which will facilitate cost-effective fabrication of free-standing compliant interconnects and investigated key factors which impact assembly yield of free-standing compliant interconnects. Ultimately the proposed approaches are demonstrated by developing an innovative compliant interconnect called FlexConnects. Hence, through this research it is expected that the developed compliant interconnect would address the needs of first level interconnects over the next decade and eliminate a bottleneck that threatens to impede the exponential growth in microprocessor performance. Also, the concepts developed in this research are generic in nature and can be extended to other aspects of electronic packaging.