Patent Application
20060270106
The present invention relates generally to a system and method for integrated circuits, and more particularly to a system and method for a polymer encapsulated solder lid attach.
Heat dissipation requires consideration when designing packaging for integrated circuits. In high performance applications, such as microprocessors, digital signal processors, controllers for high-speed communications systems, and so forth, it is not uncommon to have to dissipate hundreds of watts of power.
A flip-chip package is commonly used for these high power applications. In a flip-chip package, a top surface of an integrated circuit die where the integrated circuits are actually formed is flipped over and directly attached to a substrate via solder bumps and a bottom surface of the integrated circuit die is typically attached to a lid that is attached to a heat sink. The heat generated by the integrated circuitry is primarily removed through the bottom surface of the integrated circuit die.
A material that has been commonly used to attach the lid to the bottom surface of the integrated circuit die is a polymer, such as an epoxy. The epoxy provides a good bond between the bottom surface of the integrated circuit die and the lid while remaining relatively compliant so that stresses due to thermal expansion do not cause delamination and separation. In some cases, particles of a metal, such as silver, can be added to the polymer to help improve the thermal conductivity of the polymer.
Another commonly used material to attach the lid to the bottom surface of the integrated circuit die is a metal, such as solder. The use of a metal can greatly increase the thermal conductive properties of the attachment material and help with heat dissipation.
One disadvantage of the prior art is that the polymer, even with the addition of the metal particles, does not have as good a thermal conductivity as a metal material. Therefore, in certain situations, the polymer may not be able to sufficiently transfer an adequate amount of heat. This can lead to an overheating of the integrated circuit die, which can lead to a failure of the integrated circuit die.
A second disadvantage of the prior art is that a metal, such as solder, is relatively inflexible. Therefore, after a relatively low number of thermal cycles, it may be possible for delamination to occur in the interface between the lid, the solder, and the integrated circuit die. When this occurs, very little to no heat can be transferred between the integrated circuit die and the heat sink and the integrated circuit die may suffer a catastrophic failure due to overheating.
These and other problems are generally solved or circumvented, and technical advantages are generally achieved, by preferred embodiments of the present invention which provides a system and method for a polymer encapsulated solder lid attach.
In accordance with a preferred embodiment of the present invention, a combination attach for use in attaching a lid to an integrated circuit die is provided. The combination attach includes one or more metallic islands that are distributed throughout the combination attach and a polymer encapsulant that encircles each metallic island and binds the metallic island in place. The one or more metallic islands overlay one or more heat producing portions of the integrated circuit die.
In accordance with another preferred embodiment of the present invention, a method for attaching a lid to an integrated circuit die is provided. The method includes attaching the integrated circuit die to a substrate, applying a combination attach to a bottom surface of the integrated circuit die, placing the lid over the combination attach, and fixing the lid to the integrated circuit die.
In accordance with another preferred embodiment of the present invention, a packaged integrated circuit is provided. The packaged integrated circuit includes an integrated circuit die that is attached to a substrate via contacts on a top surface that also contains integrated circuitry, one or more metallic islands attached to specific portions of a bottom surface of the integrated circuit die, a lid attached to the one or more metallic islands, and a polymer encapsulant encircling each of the one or more metallic islands. The specific portions of the bottom surface of the integrated circuit die are portions that produce heat. The polymer encapsulant is attached to both the integrated circuit die and the lid.
An advantage of a preferred embodiment of the present invention is by encapsulating the metal islands in a polymer material, the different thermal characteristics of the polymer material can help to bind the metal island in place during the thermal cycles to prevent delamination and separation.
A further advantage of a preferred embodiment of the present invention is that the use of a plurality of metal islands instead of a single large monolithic sheet can help reduce the negative effects of shrinkage and expansion during a thermal cycle since the smaller dimensions of the metal islands will experience a lesser amount of shrinkage and expansion. This can further reduce the likelihood of delamination and separation.
Yet another advantage of a preferred embodiment of the present invention is that the encapsulation of the plurality of metal islands with a polymer can help to reduce the likelihood of delamination and separation since the polymer can help to bind the plurality of metal islands in place while the package experiences cool down or heat up. The binding of the plurality of metal islands can help to keep the plurality of metal islands from shifting, which could lead to delamination and separation.
The foregoing has outlined rather broadly the features and technical advantages of the present invention in order that the detailed description of the invention that follows may be better understood. Additional features and advantages of the invention will be described hereinafter which form the subject of the claims of the invention. It should be appreciated by those skilled in the art that the conception and specific embodiments disclosed may be readily utilized as a basis for modifying or designing other structures or processes for carrying out the same purposes of the present invention. It should also be realized by those skilled in the art that such equivalent constructions do not depart from the spirit and scope of the invention as set forth in the appended claims.
For a more complete understanding of the present invention, and the advantages thereof, reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
a and 1b are diagrams of prior art designs for an attach used to attach a lid to an integrated circuit die;
a through 2c are diagrams of combination attaches with metallic islands intended for high heat producing hot spots on an integrated circuit die, according to a preferred embodiment of the present invention;
a and 7b are diagrams of sequences of events in the manufacture of flip-chip packages, wherein a lid of the flip-chip package is attached to an integrated circuit die with a combination attach, according to a preferred embodiment of the present invention.
The making and using of the presently preferred embodiments are discussed in detail below. It should be appreciated, however, that the present invention provides many applicable inventive concepts that can be embodied in a wide variety of specific contexts. The specific embodiments discussed are merely illustrative of specific ways to make and use the invention, and do not limit the scope of the invention.
The present invention will be described with respect to preferred embodiments in a specific context, namely an attach layer for use in attaching a lid to an integrated circuit die in high-power flip-chip packages. The invention may also be applied, however, to other packaging technologies wherein an integrated circuit die is attached to a surface where thermal transfer is important and the integrated circuit die is not encapsulated by a material to lock the integrated circuit die to the surface, such as in an overmolded wirebond package at an interface between the die and a lead frame pad.
With reference now to
Since high-performance integrated circuits typically generate a large amount of heat, they require an efficient way to dissipate the heat. In a flip-chip package, the integrated circuit die 100 can be attached to a lid 120 that can have good thermal conductive properties. In many instances, a heat sink (not shown) is also attached to the lid 120 to enhance the heat dissipation qualities of the lid 120. The lid 120 can be attached to a back surface of the integrated circuit die 100, wherein the back surface of the integrated circuit die 100 is a surface of the integrated circuit die 100 that is opposite of the surface (the top surface) that contains integrated circuitry and the solder bumps 110. An attach 125 can be used to couple the lid 120 to the back surface of the integrated circuit die 100.
With reference now to
Polymer encapsulants provide good physical bonds but are not very good thermal conductors. The inclusion of metallic particles into polymer encapsulants can increase the thermal conductivity of the polymer epoxies without significantly weakening the physical bonding properties of the polymer encapsulants. Since polymer encapsulants tend to remain relatively soft and ductile, they can deform under the differential expansion and contraction that occurs in a thermal cycle. Therefore, polymer encapsulants tend to not delaminate or separate, even after a large number of thermal cycles. A metallic material, such as solder (lead or lead-free), can provide good physical bonds and excellent thermal conductivity. However, a bond formed with solder tends to be rigid and the physical bond made by the solder and between the integrated circuit die 100 and the lid 120 can be susceptible to delamination and separation due to the differential expansion and contraction that occurs in the different materials used in a flip-chip package after a relatively small number of thermal cycles. Once delamination and separation occurs, the thermal conductivity can be greatly reduced and the integrated circuit die 100 tends to rapidly self-destruct due to the inability to dissipate the heat that is generated.
Typically, an integrated circuit die will not produce the same amount of heat across its surface. A normal integrated circuit die will have hot spots on its surface that are dependent upon the circuitry located at the spots. Therefore, it may not be necessary to provide the same amount of thermal conductivity across the entire surface of the integrated circuit die. For example, in portions of the integrated circuit die that do not generate much heat, a less effective thermal conductor can be used, while in portions of the integrated circuit die that generate large amounts of heat, a highly effective thermal conductor should be used to remove as much of the heat as rapidly as possible. It is, therefore, possible to use a metallic material in the attach over portions of the integrated circuit die that generate a lot of heat, while over portions that generate little heat, a polymer encapsulant can be used in the attach. The use of the polymer encapsulant can help to restrict the expansion and contraction of the metallic portions of the attach. Additionally, the reduced size of the metallic attach can further mitigate the negative effects of thermal expansion and contraction, since the overall dimension changes during thermal expansion and contraction are smaller with the smaller metallic pieces.
With reference now to
The polymer encapsulant 215 can serve multiple purposes. A first purpose of the polymer encapsulant 215 is to provide a heat conduit from the integrated circuit die 100 to the lid 120 for portions of the integrated circuit die 100 not under a metallic island 210. A second purpose of the polymer encapsulant 215 is to bind the metallic island 210 in position. The binding action of the polymer encapsulant 215 can help to prevent the metallic island 210 from moving and/or shifting during expansion and contraction in a thermal cycle. This can help to eliminate (or reduce) delamination and separation of the metallic island 210 from the integrated circuit die 100 or the lid 120. The fact that the polymer encapsulant 215 can remain relatively compliant can help keep the metallic island 210 in place, even while it is expanding and contracting.
With reference now to
With reference now to
With reference now to
Once the lid 120 has been attached to the integrated circuit die 100, the polymer encapsulant 215 can be deposited. According to a preferred embodiment of the present invention, the lid 120 can have one or more holes 305 that will permit a dispensing needle 310 to be inserted. The dispensing needle 310, once inserted, can deposit the polymer encapsulant 215. The polymer encapsulant 215 can then flow throughout empty voids in the combination attach 205, filling the voids. The polymer encapsulant 215, depending upon the characteristics of the material, can cure automatically or may require the application of heat.
The holes 305 in the lid 120 may be located at specific locations that can be dependent upon the layout pattern of the metallic islands 210, or they may be located at regular points on the lid 120, and depending upon the layout pattern of the metallic islands 120, some of the holes 305 may be usable for the injection of the polymer encapsulant 215 and some may not be usable due to blockage by a metallic island 120. The dispensing needle 310 can be lowered into a hole 305 and the polymer encapsulant 215 can be deposited through the dispensing needle 310. Depending upon the characteristics of the polymer encapsulant 215, the use of a single hole 305 may be adequate to dispense the polymer encapsulant 215 throughout the combination attach 205. However, multiple holes 305 can be used to ensure that the polymer encapsulant 215 is properly distributed throughout the combination attach 205. Multiple dispensing needles 310 can be used to shorten the time required to deposit the polymer encapsulant 215. The integrated circuit die 100 has already been encapsulated by the encapsulating layer 115, so the polymer encapsulant 215 can be permitted to flow freely throughout the flip-chip package 300 should it be necessary to do so to ensure that all voids in the combination attach 205 are filled.
With reference now to
According to a preferred embodiment of the present invention, depending upon the physical characteristics of the polymer encapsulant 215, the dispensing needle 405 can be extremely thin and can be inserted into an existing gap between the lid 120 and the substrate 105. A single design for the lid 120 can be used for a wide variety of integrated circuit dies 100 and combination attach 205 as long as the integrated circuit dies 100 and combination attach 205 can fit within the lid 120. The flip-chip package 400 may be flipped onto its lid 120 prior to the insertion of the dispensing needle 405 to have gravity assist in the dispersion of the polymer encapsulant 215.
With reference now to
With reference now to
The design of the combination attach can begin with a determination of hot spots on the integrated circuit die (block 605). This can be done via simulation studies of the integrated circuit die or via measurements of actual integrated circuit die. Using information regarding the hot spots, a layout for the metallic islands of the combination attach can be made (block 610). The metallic islands should be laid out so that each hot spot on the integrated circuit die is covered by a metallic island. A single metallic island can cover more than one hot spot. This may be an effective way to reduce complexity of the layout of the combination attach, especially when there are a large number of hot spots of a relatively small size. Alternatively, one single metallic island can cover the full die surface with polymer encapsulant surrounding it. In addition to having each hot spot covered by a metallic island, the layout of the combination attach should consider other layout rules such as spacing the metallic islands so that sufficient spacing exists between adjacent metallic islands so that adequate capillary action is present to enable the polymer encapsulant material to fill voids between the metallic islands, a minimum thickness for the metallic islands, and so forth (block 615). The design of the combination attach can then be used to create print screens for use with combination attaches that are made during manufacture of the flip-chip or manufacture preformed combination attaches.
With reference now to
Once the material used for the metallic islands, such as solder paste, has had a chance to set, the lid can be placed over the metallic islands and the flip-chip packaged can be placed through an oven to melt the material used in the metallic islands and bind the lid to the integrated circuit die (block 715). After the flip-chip package has had an opportunity to cool after the binding, the polymer encapsulant material can be injected to complete the formation of the combination attach (block 720). Depending upon the design of lid, the polymer encapsulant can be injected through holes in the lid or through an opening in the side of the flip-chip package. The polymer encapsulant can then be allowed to cure (block 725), which may involve the application of heat or simply permitting the polymer encapsulant to cure at room temperature, depending upon the polymer encapsulant itself. The flip-chip package is then complete and is ready for additional testing and packaging to make it ready for distribution.
As shown in
Although the present invention and its advantages have been described in detail, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.
Moreover, the scope of the present application is not intended to be limited to the particular embodiments of the process, machine, manufacture, composition of matter, means, methods and steps described in the specification. As one of ordinary skill in the art will readily appreciate from the disclosure of the present invention, processes, machines, manufacture, compositions of matter, means, methods, or steps, presently existing or later to be developed, that perform substantially the same function or achieve substantially the same result as the corresponding embodiments described herein may be utilized according to the present invention. Accordingly, the appended claims are intended to include within their scope such processes, machines, manufacture, compositions of matter, means, methods, or steps.
