Abstract:
Method for the preparation of electrodeposited or galvanically deposited bumps for the bonding of integrated circuits, characterized by two subsequent metal depositions, deposited without an external current source (chemical metal deposition) on a metallization 1, the first deposition being thicker than the second and the second deposition being more even or more regular throughout a large area than the first one.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a process for the preparation of bumps on integrated circuits (ICs). The object is to avoid an (expensive) sputtering process required for the preparation of prior art bumps. 
     2. Prior Art 
     The flip-chip--or Tape Automated Bonding (TAB)--technology is a bonding process interconnecting the chip via &#34;bumps&#34; with a printed or prepared circuit structure on (semiconductor-) substrates. These processes allow high connection rates on a very small surface, lower inductivities as compared with wire bondings and an improved transfer of heat or thermal conveyance. At present, solder bumps or gold bumps are commonly used in said flip-chip and TAB technology. These processes require entire wafers as well as the use of thin-film-technologies (sputtering, photoresist-structuring) in combination with galvanic metal deposition processes. 
     Wafers comprising aluminum bond pads and a passivation layer are used for the galvanic shaping or molding of bumps in photosensitive resist. The passivation layer covers the entire wafer--thus sufficiently protecting the active elements--only the aluminum bond pads are left open and are overlapped on the edges by the passivation. The bumps may not be deposited directly on said aluminum pads, because metallic interconnections are formed at the surfaces adjoining the aluminum. Therefore, an adhesion and diffusion barrier layer (e. g. TiW) is prepared by sputtering after a preceding sputtering and etching process. A second thin gold or copper layer is sputtered, to form a basis for the gold or solder bumps to be deposited by galvanization. Said layer system is also called &#34;under-bump-metallization&#34;. A galvanic mask consisting of photosensitive resist is required for the preparation of the bumps. In order to obtain a high contact density, the horizontal growth may be limited by using a thick photosensitive resist. The galvanic shaping of the bumps is effected in a respective metal bath. 
     SUMMARY OF THE INVENTION 
     The present invention relates to a process for the deposition of a metallic under-bump-metallization and plating base for bumps to be shaped by galvanization, said process being effected by a metal deposition without outer or external current source (chemical metal deposition). The inventive process avoids the expensive sputtering process and reduces the cost for the &#34;bumping&#34;. Metal plating or deposition processes without external current source are less expensive and surprisingly achieve a comparable quality of the bumps without having to accept an undesirable diffusion in the bump basis area. 
     In ideal circumstances, this kind of layered systems comprising an under-bump-metallization and a plating base achieves the following characteristics: 
     The diffusion of gold or solder through the under-bump-metallization to the aluminum and vice versa is blocked. 
     The conductivity of the plating base is high and the contact resistances to the adjoining layers are low. 
     The mechanical requirements, such as good adhesive effect and resistibility to mechanical and thermal stresses are satisfied. 
     The thermal conductivity is high. 
     The thickness and structure of the layer are regular (even) throughout the entire wafer surface. 
     The invention is described in detail on the basis of two embodiments, however not to be regarded as limiting the scope of the invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIGS. 1a to 1e schematically show a first process flow A as first embodiment of a galvanic bump forming. 
     FIGS. 2a to 2f schematically show a second process flow B as second embodiment of a galvanic bump forming. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In the Figures, an aluminum bond pad 1 is applied to a substrate 3 which may be a semiconductor type (Si, Ge) or a PCB (printed circuit board) comprising several conductive paths to form a connector for bonded chips. A passivation 2 is deposited on the edges of said aluminum basis 1, where it arches or vaults slightly. The passivation covers--with the exception of the aluminum pads 1--the surface of the substrate 3. 
     Said aluminum basis 1 is coated with a metallization being comparable in its thickness and consisting preferably of nickel, so that a conductive interconnection between basis 1 and metallization 4 is provided. The thickness or height of said metallization 4 is provided to achieve approximately the height or level of the edge curvature 2a of said passivation layer 2 or to exceed it distinctly to substantially (compare FIG. 1b and FIG. 2b). Said metallization 4 is coated with a conductive layer (plating base) 5 being thin with respect to said metallization 4 or said aluminum bond pad 1. A considerably higher metal bump 7, forming the contact bump, is applied to said plating base 5 in the area of said metallization 4 onto said bond pad 4,1. The application is effected by galvanic deposition, which is controlled by openings of a surrounding very thick photosensitive resist 6. Said bump 7 is deposited from a galvanic bath in said openings or windows 6a (cf. FIG. 2e or 1d). 
     After removal of said photosensitive resist 6, said bump 7 remains protruding on said substrate 3, on top of said plating base 5, said metallization 4 and said aluminum bond pad 1. 
     Outside of or around said bump 7, said plating base 5 may be removed, e. g. by etching. 
     The two processes described below differ particularly by FIGS. 1c and 2c, in which firstly (process A) there is no application of a catalytic polymer coating 8, but said passivation 2 and said metallization 4 are coated directly with said plating base 5, and in which secondly (process B) said metallization 4 is coated with a suitable polymer layer 8 prior to being removed on a large area in order to form an even surface consisting of small separated metallic areas 4a and a large polymeric area 8a in the intermediate space. 
     Process Flow A (FIG. 1) 
     1) Chemical deposition 4 of nickel or gold on said aluminum bond pads 1 to provide an under-bump-metallization (nickel thickness approx. 0.5-10 μm, gold immersion approx. 0.2 μm). The height of said deposition 4 is approximately the same as the height of said curvature 2a of said passivation 2. 
     2) Chemical metal deposition of a plating base 5 by activating passivation 2 (chemical gold or nickel or copper or palladium). An electroless nickel deposition and its characteristics is disclosed in Lee, et al., Structures and Corrosion characteristics of electroless Ni--Mo--P-Alloy deposits, Plating and Surface Finish, 1991, September, pages 82ff. 
     3) Application of photosensitive resist 6 (form and thickness h 6  corresponding to the desired form and height h 7  of the bump). 
     4) Preparing an opening 6a into said photosensitive resist 6. 
     5) Galvanic metal deposition (e.g. Pb, Sn, Au, In) for the formation of a bump 7 in given height and lateral dimension. 
     6) Stripping of photosensitive resist 6 outside of bumps 7. 
     7) Outside etching of plating base 5. 
     Process Flow B (FIG. 2) 
     1) Chemical deposition 4 of nickel or gold on said aluminum bond pads 1 to provide an under-bump-metallization (nickel thickness approx. 0.5-10 μm, gold immersion approx. 0.2 μm), slightly overlapping passivation 2 which surrounds said bond pads 1. 
     2) Application of a photo-structurable polymer coating 8 (e. g. photosensitive resist): 
     a) with catalytic effect; 
     b) with subsequent activation (e. g. palladium activator). 
     3) opening of said polymer coating 8, which is located on top of said under-bump-metallization 4, in order to open or uncover a window 4a into said metallization or removal of a part of the surface area in order to obtain an even surface of said metallization 4a and said polymer coating 8a. 
     4) Chemical metal deposition of a plating base 5 (chemical gold or nickel or copper or palladium) which is thin with respect to said metallization 4. 
     5) Application of a thick photosensitive resist 6 (lateral form and thickness h 6  corresponding to the desired bump-form and bump-height h 7  respectively). 
     6) Opening said photosensitive resist 6 to form window 6a on top of said aluminum bond pad 1. 
     7) Galvanic metal deposition (e.g. Pb, Sn, Au, In) to form a galvanic metal bump 7 in said window 6a. 
     8) Stripping said photosensitive resist 6 outside of said galvanic bumps 7. 
     9) Etching of said plating base 5 outside of said galvanic bumps 7. 
     10) Stripping of said polymer coating 8. 
     Both processes may be used to achieve bumps 7 of galvanic nature in a cost effective and stable manner at reasonable process time. No underbump-diffusion may take place although a cheap chemical deposition of one or two layers underneath said galvanic main part of the bump has been selected, generally so far regarded not to be able to substitute galvanically deposited thin plating layers with respect to sufficient physical necessities.