Patent Document

BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates generally to semiconductor packaging and more particularly to a ceramic column grid array package formed with polymer reinforcement of the columns on a chip carrier substrate. 
     2. Description of Related Art 
     Ceramic column grid array packages are used in many high performance application specific integrated circuits and microprocessor chips. In a typical manufacturing process of bonding, assembly and test, the wire connections for a ceramic column grid array are attached near the end of the manufacturing cycle, thus minimizing handling damage. A problem with wire column grid array processing is that during printed circuit card rework, the columns on the grid array packages may come off from the package substrate side and stay behind on the printed circuit card. Multiple localized heating on the printed circuit card side to remove these columns is time and labor intensive and may damage the printed circuit card by causing land delaminations. 
     A purpose of the present invention is to provide an enhanced ceramic column grid array and method for mechanically stabilizing the wires of the column grid on its substrate. 
     Another purpose of the present invention is to provide an enhanced column grid array which may be reworked wherein the column grids stay with their substrate and do not remain with the printed circuit card. 
     SUMMARY OF THE INVENTION 
     The above and other purposes which will be apparent to one skilled in the art are achieved by the present invention which in one aspect a polymer having a low glass transition temperature is coated on the substrate after attachment of the column grid array wires. Upon curing of the polymer, the polymer mechanically reinforces the base or fillet of the column grid array wires to enhance the attachment of the wires to the ceramic column grid substrate. The polymer may be injected or spin coated onto the substrate, then cured at a temperature below the melting point of the wire column solder material. Upon removal of the ceramic column grid array mounted on a printed circuit card, all of the wire grids will remain with the array package and none of the columns will remain with the card itself. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The foregoing and other purposes, aspects and advantages will be better understood from the following detailed description of a preferred embodiment of the invention with reference to the drawings, wherein: 
     FIG. 1 illustrates a typical column grid array package module after assembly to a card; 
     FIG. 2 illustrates a typical column grid array package module after removal from a printed circuit card; 
     FIG. 3A illustrates a detailed view of the eutectic solder bonding a solder column to a card and a substrate; 
     FIG. 3B illustrates a detailed view of a wire column structural failure during printed circuit card rework; 
     FIG. 4A illustrates a polymer enhanced column grid array coated according to the method of the present invention; 
     FIG. 4B illustrates a detailed view of a polymer encapsulated wire column; 
     FIG. 5A illustrates a polymer enhanced module after printed circuit card rework; and 
     FIG. 5B illustrates a detail view a wire column having polyimide reinforcement according to the present invention after printed circuit card rework. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The present invention is useful for semiconductor packages such as application specific integrated circuits and microprocessors employing ceramic column grid array packaging techniques. The invention is particularly suited to wire column grid arrays. A wire ceramic column grid array is an often used package structure and the method for forming its structure is known to those skilled in the art. The wire ceramic column grid array is attached at the very end of the bonding, assembly and test manufacturing cycle of semiconductor integrated circuits and, thus, minimizes handling damage. 
     A ceramic column grid array module  10  as shown in FIG. 1 is typically mounted onto a printed circuit card or board  40  . The ceramic column grid array module  10  is formed by securing a chip  20  to a substrate or module  30  via a plurality of solder balls  22  on pads  24 , that are on the substrate or module  30 . The substrate  30  could also have one or more electronic devices  28  such as for example, a decoupling capacitors  28 , that are also electrically connected to substrate  30  vias the pads  24  and solder balls  22 . For some applications the solder balls  22  and pads  24  could be encapsulated with an encapsulate  26 , such as, an epoxy. A thermally conductive material  16  is usually applied over the exposed surface of the chip  20  such that a direct thermal contact is made between the chip  20  and the cap or cover  14  when the cover  14  is placed over to protect the chip  20 . A cover sealant  18  is typically provided in order to secure the cap or cover  14  to the substrate or module  30 . The substrate  30  is typically attached to a printed circuit card via input/output means  32 , such as wire columns  32  which are bonded using eutectic solder  36  to pads  34  on the substrate, as more clearly shown in FIG.  3 A. The wire columns of the grid array are typically bonded to a printed circuit card  40  by use of eutectic solder  38  to card lands  42 , as more clearly shown in FIG.  3 A. 
     The printed circuit card is usually made up of one or more layers of conducting films comprising an organic laminate composite. Sometimes during testing of printed circuit cards a failure occurs and a ceramic column grid array package module must be removed from the printed circuit card. When doing this the ceramic column grid array often leaves wire interconnections on both the chip carrier or module substrate as well as on the organic printed circuit card. The result after removal of the column grid array module  10  from the card  40  is shown in FIG. 2 where some of the wire columns are attached to the substrate  30  and some remain attached to the printed circuit card  40 . Multiple localized heating on the card side is needed to remove these columns that remain on the card. The columns are removed by a time and labor intensive process in which a hand held hot gas tool is used to heat up the removal site and when the eutectic solder interface melts, the columns are picked up by a vacuum nozzle. Care must be exercised to prevent damage of the card due to conductor wiring delaminations on the card. 
     A detailed view of the wire column  32  is shown in FIG.  3 A. The wire column  32  is typically formed of a solder alloy having a high melting point in the range of 270-300 C. The wire column material is wettable with low melting point solder. The high melting material forming the wire columns is made of lead/tin where the tin ranges from about 5% to about 30%. Small amounts of additional material such as silver at about 3% may be used to form the wire columns. Alternatively, the wire columns  32 , may be formed of near solid tin, such as about 99% tin/1% germanium or about 97% tin/3% copper. The diameter of the wire column  32  is in the range of about 0.3-0.5 mm, which is sufficient to provide good electrical interconnections for the microelectronic devices. The height of the wire columns  32 , is in the range of about 1.0 mm to about 2.5 mm. 
     As shown in FIG. 3A the wire column  32 , is attached to the substrate bottom surface metallurgy on a pad  34  with eutectic solder  36 . Similarly, the other end of the wire column  32 , is attached to the printed circuit card land  42  using an eutectic solder  38 . The eutectic solder forms a fillet, that is a concave junction where the wire column meets the pad  34  or land  42 . The eutectic solder may be 63/37 tin/lead for both item  36  and/or  38  or one could use other ratios of lead to tin which give different melting points. The same solder may be used for both the bonds  36  and/or  38 , however, a different solder material could also be used for each. 
     A common failure mechanism as shown in FIG. 3B where upon removal of the module, the eutectic solder  36  breaks near the module pad  34 , as shown in the FIG. 3B, or breaks at the eutectic solder bond  38  near the printed circuit card land  42 , (not shown). 
     The present invention utilizes a standard ceramic wire column grid array attached to the substrate in the same manner as previously shown with the addition of a thin polymer coating  50 , in such a way as to cover the fillet of the columns  32 . The polymer chosen must have appropriate coating and temperature properties. The polymer  50 , must be capable of being dispensed or spin coated to provide a thin conformal coating to the fillets of the column. A typical thickness of the cured film is in the range of about 5 to about 50 microns with a preferred thickness being about 5 to about 15 microns. Alternative methods of coating such as injecting small amounts of polymer at one or more corners of a column grid array and allowing surface tension to spread the material may also be used. The substrate  30  is typically made of ceramic, but an organic substrate or silicon substrate may be used provided good adhesion of the polymer to substrate can be obtained. 
     The polymer used must be cured at a temperature below the melting point of eutectic used in the column grid array connections. Typically, the lead/tin eutectic melting point is around 180° C. The polymer must be, therefore, cured below this temperature. The glass transition temperature of the polymer, that is the temperature that the polymer soften, should be less than the melting point of the lead tin, used to form the wire columns. 
     The polymer  50 , should adhere well to the ceramic substrate  30 , and the bottom surface of metal pads  34 , and have adequate adhesion to the lead/tin solder  36 , surface which bonds the wire columns  32 , to the substrate pads  34 . The thin polymer coating  50 , will prevent the  90 / 10  solder bonded columns from separating from the molten eutectic during card rework. The polymer  50 , will provide a mechanical reinforcement to the ceramic column grid array to ensure that the columns  32 , will remain with the semiconductor module and the module can be reused if required. 
     A preferred polymer material is a siloxane polyimide having a glass transition temperature of about 142° C. An approximate 4-5% percent solution of siloxane polyimide in1-methyl-2-pyrrolidinone (NMP) was found to work well as the polymer coating. Another coating found to work well is the polyimide Ultem 1040 (Tm) from General Electric which has a glass transition temperature of about 180° C. Other low temperature solder interfaces such as tin/antimony have a melting point of about 232° C. or lead/tin solders having a melting point range of between about 190 to about 240° C. or other various ratios can be used instead of the lead/tin eutectic solder. In addition, transient liquid solder interfaces such as Palladium doped eutectic solder can also be used with this invention. 
     The process for forming the polymer enhanced ceramic column grid array is as follows. The ceramic column grid array module  10 , such as the one shown in FIG. 4A, is placed in a plasma asher to clean the surface of the substrate  30 . Following the ashing step, a thin layer of adhesion promoter such as A1100, gamma-aminopropyltriethoxysilane, a silane based coupling agent from Union Carbide is coated as a thin layer on the substrate. Then the substrate is heated to between 105 and about 110° C. and an appropriate siloxane polyimide solution is dispensed on the ceramic substrate. The dispensing can be done either along the edges of the column on each side or on the four corners. The siloxane polyimide, at a substrate temperature of between about 100 and about 120° C. will wick along the columns to form a thin coating on the fillets of the wire column to about 20 to 40 mils up the column shanks from the input-output pads. The polyimide coated substrate is cured in a nitrogen ambient furnace at between about 150 and about 160° C. for one to two hours to cure the polyimide. 
     FIG. 4B is a closeup view of a polymer encapsulated column fillet which shows the fillet area of the wire columns  32  at the solder bond  36  have been coated with the polyimide film. The coating on the shank of the wire columns tapers off to a few microns 30 to 40 mils away from the base of the fillets where the column joins to the substrate input-output pads. 
     Upon removal of the module shown in FIG. 5A from an organic printed circuit card, The polyimide mechanically strengthens the column grid array so that the columns stay with the substrate upon removal of the module shown in FIG. 5A from a printed circuit card. As shown in FIG. 5B, the wire column will detach from the card leaving at most a small amount of eutectic lead tin solder on the card land  42 , with the wire column  32 , remaining with the substrate. Since the polyimide has a glass transition temperature less than 180° C., during removal of the module from the circuit card during rework, the polyimide becomes compliant and prevents the eutectic solder from moving when the solder is molten. As a result the lead/tin columns remain joined to the eutectic solder interface at the module wire column joint and the module is available for reuse. 
     Having thus described the present invention and its preferred embodiments in detail, it will be readily apparent to those skilled in the art that further modifications to the invention may be made without departing from the spirit and scope of the invention as presently claimed.

Technology Category: y