Surface planarization of Cu and CuNiSn Micro-bumps embedded in polymer for below 20μm pitch 3DIC applications

De Preter, Inge, Derakhshandeh, Jaber, Heylen, Nancy, Van Acker, Lut, June Rebibis, Kenneth, Miller, Andy, Beyer, Gerald, Beyne, Eric

22 July 2016

Planarization techniques such as Surface planer (better known as Fly-cut) and chemical-mechanical polishing (CMP) can be used to improve the bump roughness and bump height uniformity within the die and wafer which can be beneficial for solder based bump stacking and Cu-Cu direct bonding [1]. In this paper the influence of both planarization techniques on 20μm pitch Cu and CuNiSn bumps embedded in polymer are studied. The polymer protects the bumps from the shearing force of the planarization process and will later serve as a underfill material for the resulting gap of a 3D stack. The microbump planarization process will be discussed. Furthermore characterization of the bump height uniformity across the wafer using SEM and High Resolution Profilometry (HRP) is reported.

surface planarization

microbumps

polymer

ddc:620

Polymere

SAMs (self-assembled monolayers) passivation of cobalt microbumps for 3D stacking of Si chips

Hou, Lin, Derakhshandeh, Jaber, Armini, Silvia, Gerets, Carine, De Preter, Inge, June Rebibis, Kenneth, Miller, Andy, De wolf, Ingrid, Beyne, Eric

22 July 2016

In this paper SAM (self-assembled monolayers) is used to passivate cobalt microbumps for 3D-stacking of Si chips. The SAM deposition process is optimized, using input from characterization techniques such as water contact angle measurement, ATR, AFM and XPS analysis in order to form a monolayer of Thiols-SAM on cobalt microbumps. A 3D stacked Si chips test vehicle was used to demonstrate the effectiveness of the SAM coating on cobalt bumps by measuring the electrical continuity of daisy chains.

microbumps

Co UBM

3D stacking

self-assembled monolayer

TCB

ddc:620

Monoschicht

Cobalt

Selbstorganisation

Surface planarization of Cu and CuNiSn Micro-bumps embedded in polymer for below 20μm pitch 3DIC applications

De Preter, Inge, Derakhshandeh, Jaber, Heylen, Nancy, Van Acker, Lut, June Rebibis, Kenneth, Miller, Andy, Beyer, Gerald, Beyne, Eric

22 July 2016

Planarization techniques such as Surface planer (better known as Fly-cut) and chemical-mechanical polishing (CMP) can be used to improve the bump roughness and bump height uniformity within the die and wafer which can be beneficial for solder based bump stacking and Cu-Cu direct bonding [1]. In this paper the influence of both planarization techniques on 20μm pitch Cu and CuNiSn bumps embedded in polymer are studied. The polymer protects the bumps from the shearing force of the planarization process and will later serve as a underfill material for the resulting gap of a 3D stack. The microbump planarization process will be discussed. Furthermore characterization of the bump height uniformity across the wafer using SEM and High Resolution Profilometry (HRP) is reported.

info:eu-repo/classification/ddc/620

ddc:620

Polymere

SAMs (self-assembled monolayers) passivation of cobalt microbumps for 3D stacking of Si chips

Hou, Lin, Derakhshandeh, Jaber, Armini, Silvia, Gerets, Carine, De Preter, Inge, June Rebibis, Kenneth, Miller, Andy, De wolf, Ingrid, Beyne, Eric

22 July 2016

In this paper SAM (self-assembled monolayers) is used to passivate cobalt microbumps for 3D-stacking of Si chips. The SAM deposition process is optimized, using input from characterization techniques such as water contact angle measurement, ATR, AFM and XPS analysis in order to form a monolayer of Thiols-SAM on cobalt microbumps. A 3D stacked Si chips test vehicle was used to demonstrate the effectiveness of the SAM coating on cobalt bumps by measuring the electrical continuity of daisy chains.

info:eu-repo/classification/ddc/620

ddc:620

Monoschicht; Cobalt; Selbstorganisation