WAFER SCALE THIN FILM PACKAGE

Abstract

A chip module having a chip with a flexible multilayer redistribution thin film attached thereto for connection to a substrate. The thin film acts as both a redistribution medium with multiple layers of redistribution metallurgy for chip power and signals and as a compliant medium to relieve stresses caused by thermal expansion mismatch between chip and substrate. Modules comprising chip and thin film may be fabricated at the chip or wafer level. The upper surface of the thin film has an array of pads matching the array of pads on the chip or wafer while the lower surface has pads matching those of the substrate. The multilayer thin film is first formed on a temporary substrate and then the chip is to the thin film before release from the temporary substrate. After release, the module is ready for mounting to the second level packaging substrate, such as a chip carrier or PCB. Where the multilayer thin film is formed directly on a wafer, the wafer is then diced to form the module.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to electronic packaging and methods of fabricating same. More particularly, the present invention relates to semiconductor chip packaging using a multilayer thin film for chip attachment to a substrate.

2. Background and Related Art

Ever increasing industry demand for smaller and smaller electronic packages with low profile, higher area density and increasing number of input/output connections (I/Os) has led to increasing demand for the Chip Scale Package (CSP). Use of such packages may be found in small portable products, such as cellular phones, pagers, and the like. However, it is known that CSPs have somewhat limited applications because of the limited number of I/Os due to solder interconnect reliability constraints. As feature sizes of the semiconductor chip packages decrease, as in the case of CSPs, and the I/O connection count increases, so too will the number of chips packaged in a given area. This will increase the heat dissipated by each of the chips which will, in turn, increase the thermal mismatch stresses between chip and substrate, the latter of which will decrease the interconnect reliability of the package. Various efforts have been made in the prior art to address the thermal mismatch problem. In addition, various efforts have been made to improve interconnect reliability and reduce cost by, for example, fabricating CSPs at the wafer level. However, these efforts have not been totally successful and have involved relatively complex and costly assemblies with limited capability.

In view of the limitations of prior art chip packaging mentioned hereinabove, there continues a need for a relatively simple, low profile, high density, chip packaging approach which has high interconnect reliability and high I/O connection count, and which may use relatively low-cost wafer scale processing.

SUMMARY OF THE INVENTION

In accordance with the principles of the present invention, a relatively simple chip packaging approach is provided using multilayer thin film technology. The flexible thin film acts as both a redistribution layer and a stress relief layer between chip and second level interconnect substrate. More particularly, the flexible multilayer thin film acts to provide multiple layers of redistribution metallurgy for both power and signals in the X-Y plane (e.g. fanout or grid change) and also provides sufficient flexibility to connections in both the Z-direction and X-Y plane to relieve stresses caused by the thermal expansion mismatch between semiconductor chip and second level interconnect substrate, such as, a PCB.

The flexible multilayer thin film is first mounted on either a silicon die or wafer. The upper surface of the thin film has an array of pads matching the array of pads on the die or wafer while the lower surface has pads matching those of the second level interconnect substrate. The mounting of the multilayer thin film on a die creates a module for mounting to the second level substrate, such as a chip carrier or PCB. Where the multilayer thin film is formed directly on a wafer, the wafer is then diced to form the modules.

Accordingly, it is an object of the present invention to provide an improved semiconductor chip package and method for making same.

It is a further object of the present invention to provide a chip package having a flexible multilayer redistribution thin film attached thereto to form a low profile, low vertical inductance, module.

It is yet a further object of the present invention to provide a chip module comprising a flexible multilayer thin film attached to the chip which thin film acts as both a redistribution medium and stress relief medium between chip and next level of packaging.

It is another object of the present invention to provide a chip module formed by fabricating a flexible multilayer redistribution thin film on a wafer before dicing.

It is yet another object of the present invention to provide a chip package and method of making same which acts to increase interconnection reliability and I/O count and provide simple, low cost, assembly.

These foregoing and other objects, features and advantages of the invention will be apparent from the following more particular description of a preferred embodiment of the invention, as illustrated in the accompanying drawings, wherein like reference members represent like parts of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a cross-section of a partially assembled chip module, made in accordance with the present invention.

FIG. 2 shows a cross-section of a partially assembled chip package made in accordance with the present invention.

FIG. 3a shows a cross-section of an assembled chip package, made in accordance with the present invention.

FIG. 3b shows an exploded view of a portion of the chip package shown in FIG. 3a.

FIG. 4 shows a cross-sectional view of an alternative embodiment of the chip package shown in FIG. 3a.

FIG. 5 shows another embodiment of the chip package in accordance with the present invention.

FIG. 6a shows a further embodiment wherein the flexible multilayer redistribution thin film is first fabricated on a wafer.

FIG. 6b shows a cross-section of the thin-film-on-wafer of FIG. 6a.

FIG. 6c shows an exploded view of the cross-section of FIG. 6b.

DETAILED DESCRIPTION

With reference to FIG. 1, there is shown a cross-sectional view of a partially assembled chip module which view is used to facilitate a description of the process for creating the flexible multilayer redistribution thin film and attaching to a chip, in accordance with the present invention. Multilayer thin film 1 is first formed upon master glass substrate 3. The thin film may be formed by any of a variety of thin film lithography techniques known to those skilled in the art.

Fabrication of the thin film structure using conventional lithographic processing steps necessarily begins with selecting a flat, rigid substrate to ensure good feature resolution. For ease of removal of the thin film after completion of its formation, glass has been selected. To reduce thermal expansion mismatch between the chip and glass substrate 3, a glass with a CTE similar to silicon is selected, such as a Boro float glass. The glass surface for deposit may first be cleaned and then a thin release layer 8 microns thick is deposited. The release layer (not shown) is typically the same material as is used to form the thin film structure and may be deposited by spinning onto glass substrate 3. For example, a polymer, such as, polyimide may be used. The polymer release layer is then properly cured. Pads 5 may then be formed on the substrate or, alternatively, formed after the module is completed. Where pads 5 are formed at this point, they are formed in a pattern matching the pattern of the second level package to which it is to be attached. The pads may be BGA pads, for example, formed by sputtering or electroplating, for example, 10-20 microns of metal, such as copper.

A first layer of polyimide (or other polymer such as a filled PTFE or Teflon) 10-11 microns thick is then spun onto the release layer with or without pads, depending upon process choice. A pattern of vias selected according to the pattern of pads formed on the glass substrate matching the pads on the second level package to which it will be attached, is then ablated by laser ablation into the first layer of polyimide. The vias are then filled with conductive material to the underlying pads. This may be done by electroplating copper to the copper pads or filling with an electrically conductive adhesive. It is clear that other metals may also be used instead of copper. Where pads have not yet been formed, the vias may be electrolessly plated with copper.

A layer of copper is then deposited on the first layer of polyimide and in contact with the conductively filled vias. The layer of copper may be 5-6 microns thick and can be electroplated. The layer of copper is then masked with a layer of resist according to the selected metallurgical pattern of the overall redistribution pattern to leave copper lines contacting selected vias. The layer of copper is then etched, for example, by reactive ion etching. Then a second layer of polyimide is deposited upon the first layer of polyimide and copper lines. A pattern of vias is then ablated into the second layer of polyimide at selected locations to the underlying copper lines and the vias are plated with copper. Another layer of copper is then deposited upon the second layer of polyimide and copper plated vias. The second layer of copper is etched according to the desired metallurgical pattern and the process repeats until the overall redistribution pattern is achieved.

When the final layer of polyimide is formed, the pattern of metal filled vias is selected to match the pattern of conductive pads (not shown) on chip 7. Pads are then formed on these vias. Such pad may be, for example, C4 pads. FIG. 3b shows a typical 3 level redistribution thin film. It is clear that any desired number of layers of polyimide and metal may be employed, depending upon the complexity of the redistribution pattern. It is also clear that any of a variety of deposition and etching techniques may be employed to form the layers of material, vias and metallurgical patterns.

Again, with reference to FIG. 1, after forming the multilayer redistribution thin film on substrate 3 with a pattern of C4 pads on its top surface matching the pattern of pads on chip 7, high melt C4 solder balls 9, for example, are attached to the pads, as shown. Chip 7 is then positioned and attached by C4 melting of the high melt solder, as is known to those skilled in the art. Other alloy systems may also be used in place of the high melt solder, such as, eutectic SnPb, SnAgCu or SnAgBi. After attaching chip 7 to thin film 1, the chip is underfilled with any of a variety of underfills, such as an epoxy, to bond chip 7 to thin film 1. The epoxy may be with or without fillers. Examples of such epoxies are Hysol, Namics and RCE. The underfill step may be carried out by dispensing with a dispensing needle from the edge of the chip where the epoxy will penetrate by capillary action.

After the underfill step, the resulting module comprising chip 7 and thin film 1 is separated from glass substrate 3. This may be done by laser ablation, such as, with a 308 nm He—Ne laser. The detached surface of the module is then cleaned by etching, and if pads have not been previously formed, to prepare for the formation of the BGA pads. These pads may be formed, for example, by ablating a pattern of recesses for the pad areas and then plating therein a 10-20 micron layer of copper, according to the underlying pattern of vias matching the second level package to which it will be connected.

After separation from glass substrate 3, the resulting module 11 (with chip, C4-s, underfill, thin film and BGA pads) as shown in FIG. 2, is attached to a second level package, such as, PCB 13. PCB 13 is shown, for example, with an array of low temperature melt solder balls 15 matching pads 5 on module 11, as hereinabove described. Solder balls 15 are formed on BGA pads 16. As described above, other alloy systems may also be used in place of the low melt solder, such as, eutectic SnPb, SnAgCu or SnAgBi. Spacer 17 is used for alignment and reinforcement. Examples of such spacers are layers of EKJ (Dupont) or Kapton 150-200 microns thick punched or drilled with holes for aligning solder balls 15 to pads 5. The spacer not only acts to align but also acts to provide stress relief to the solder ball interconnections by redistributing stress due to thermal expansion mismatch. The spacer may be joined to the thin film redistribution layer and PCB by either a thermoplastic adhesive or adhesive tape. After alignment, the low temperature melt solder is heated to reflow the solder and make connection of chip module to PCB. It is clear that rather than use a spacer to align module 11 to PCB 13, module 11 may be otherwise aligned in contact with solder balls 15 and heated to form the connection, and then a reworkable underfill dispensed to support the connection.

The resulting assembled package is shown in FIG. 3a. An expanded view of a portion of FIG. 3a is shown in FIG. 3b. C4 connections 21 in FIG. 3b are shown separated by underfill 19. For demonstration purposes, a 3 level thin film is shown with via filled conductors 23 and layers of metallurgy 25 between the three layers of polyimide 27. It is clear that more than 3 levels of thin film may be employed, depending upon the degree of redistribution required. Spacer 17 surrounds solder connection 29, the latter making contact with BGA pads 5 of module 11 and pads 16 of PCB 13. Although reference has been made to mounting module 11 on a PCB, it is clear that other carriers may be used, such as an organic or ceramic carrier.

FIG. 4 shows an alternative embodiment of the chip package shown in FIG. 3a. As can be seen, 2 modules 11 are mounted on PCB 13. It is clear that more than 2 modules could be mounted on the PCB.

FIG. 5 shows a further embodiment where the carrier 31 for modules 11 is a substrate mounted on PCB 13. Carrier 31 may be an organic or ceramic carrier.

With reference to FIG. 6, there is shown a further embodiment wherein the flexible multilayer redistribution film is first fabricated on a wafer. FIG. 6a shows a front view of a wafer upon which individual chip multilayer redistribution thin film 33 patterns are formed. The individual patterns of thin film 33 for each chip are as described above, for purposes of redistribution of power and signal or grid change in the X-Y plane (parallel to the chip). FIG. 6b shows a cross-section of FIG. 6a wherein the individual chip patterns 33 of the overall thin film layer 34 are shown respectively formed directly on the array of chips of wafer 35. FIG. 6c shows an exploded view of FIG. 6b with BGA pads 37 shown on the final layer of an individual chip multilayer redistribution thin film. Metallurgical pattern 39 and vias 41, at the cross-section taken, are shown by way of example.

Fabrication of the overall multilayer thin film on wafer 35 is similar to that described above for fabrication of the chip level. However, it is clear that via, masking and etching patterns for the individual chip multilayer redistribution thin films 33 may vary, one from the other, or may be the same throughout the wafer. Fabrication directly on wafer 35 begins by spinning, for example, a layer of polyimide 10 to 11 microns thick onto the wafer covering the array of chips connection pads (not shown) on the wafer. Vias are then ablated in the polyimide to expose the array of chip connection pads. The vias are filled by electroplating, for example, to the chip pads to form conductive columns 41. Typically, copper would be plated to copper pads. Next, a layer of copper is deposited upon the layer of polyimide and copper filled vias and the process continues, as described above, to form layers of metal 39 of the multilayer metallurgical redistribution pattern. The final layer of polyimide is fabricated with a pattern of vias on the individual chip multilayer redistribution thin film matching the pattern of pads on the PCB to which it will be attached. As a final step in fabricating at the wafer level to form a wafer scale package, a pattern of BGA pads 37 is formed on the vias which pattern, then, matches the pattern of PCB pads. The wafer may then be diced using conventional dicing techniques, as is known to those skilled in the art. The resulting module, comprising chip and flexible multilayer redistribution thin film may then be attached to a carrier in the variety of way described above. It should be noted that whether the flexible multilayer redistribution thin film module is formed at the wafer level, as described with respect to FIG. 6, or at the chip level, as described with respect to FIG. 1, the resulting thin film of the module can be made, dimensionally, to an area the same size as the chip area to which it is attached.

It will be understood from the foregoing description that various modifications and changes may be made in the preferred embodiment of the present invention without departing from its true spirit. It is intended that this description is for purposes of illustration only and should not be construed in a limiting sense. The scope of this invention should be limited only by the language of the following claims.

Claims

1-29. (canceled)

30. A wafer scale method of forming a chip modules, having flexible thin film redistribution layer thereon comprising:

depositing a thin layer of insulating material directly on said wafer;

forming vias in said layer of insulating material to the chip electrical contacts on said wafer;

filing said vias with a conductive material;

forming a metallurgical pattern on said thin layer of insulating material and in contact with said conductive material of said vias;

alternating said steps of forming layers of insulating material with metal filled vias and forming said metallurgical patterns on said layer of insulating material to thereby form a selected redistribution pattern for chip signal and power redistribution;

forming a pattern of metal filled vias in the final layer of insulating material matching the pattern of contact pads on the substrate to which said chip modules will be attached;

forming pads on said metal filled vias of said final layer of insulating material; and

dicing said wafer to form said chip modules.

31. The method as set forth in claim 30 wherein said flexible insulating material is a polymer.

32. The method as set forth in claim 30 wherein said pads are BGA pads.

33-42. (canceled)

43. A wafer scale method of forming a chip module, comprising:

forming a flexible thin film directly on a wafer by depositing a flexible insulating material directly on the surface of said wafer having connection pads thereon; and

forming metal filled vias in said layer flexible insulating material to connect to said connection pads on said wafer;

forming metallurgy on said flexible insulating material to connect to said metal filled vias;

repeating the above steps of forming a flexible thin film of insulating material, metal filled vias and metallurgy to form a multilayer redistribution thin film;

forming vias in the final thin film layer of insulating material having a pattern matching the pattern of connection pads on the substrate to which it is to be attached; and

forming a pattern of pads on said vias in said final thin film layer of insulating material.

44. The method as set forth in claim 43 wherein said flexible insulating material is polymer.

45. the method as set forth in claim 43 comprising the further step of dicing said wafer to form chip modules ready for packaging.