Patent Application
20050218528
Embodiments of the present invention relate to a packaged semiconductive die with integrated circuitry.
An active surface of a first substrate, such as a flip-chip or an interposer, is subject to numerous electrical couplings that are usually brought to an edge of the first substrate. Heat generation is significant at the active surface of the first substrate. Electrical connections, referred variously to as balls, bumps, and others, are deposited as terminals on the active surface of a first substrate. The bumps include solders and/or plastics that make mechanical connections and electrical couplings to a second substrate, such as a printed wiring board or an interposer. The first substrate is inverted onto the second substrate with the bumps aligned to bonding pads on the second substrate. If the bumps are solder bumps, the solder bumps on the first substrate are soldered to the bonding pads on the second substrate.
Shear stress may exist on the solder joints during temperature cycling of the device. This shear stress is partially a result of a difference in the coefficients of thermal expansion (“CTE” ) of the first substrate and the second substrate.
It is desirable to reduce the shear stress on the solder joints to reduce failures.
The following description includes terms, such as “upper”, “lower”, “first”, “second”, etc. that are used for descriptive purposes only and are not to be construed as limiting. The embodiments of a device or article of the present invention described herein can be manufactured, used, or shipped in a number of positions and orientations. The term “die” generally refers to the physical object that is the basic workpiece that is transformed by various process operations into the desired integrated circuit device. A die is usually singulated from a wafer, and wafers may be made of semiconducting, non-semiconducting, or combinations of semiconducting and non-semiconducting materials. An “interposer” is often a ceramic structure.
One embodiment relates to a package that includes a die, a substrate, and an interposer there between. The interposer has a body and a channel that extends through the body. In a first embodiment, the channel is a vent hole in a die shadow region. In a second embodiment, the channel is a microchannel that lies outside of the die shadow region. In this embodiment, an underfill-mixture-reinforced solder joint is between the interposer and the substrate.
Dimensions of the channel 111 depend on a size of the die, and a volume of material dispensed, in one embodiment. In one embodiment, the channel is substantially centered on a longitudinal side of the die. In one embodiment, the channel has a length that is between 50% and 75% of the die length. A width of the channel, in one embodiment, depends upon a volume of the dispensed material. In an additional embodiment, the width of the channel is in a range from about 0.25 mm to about 2 mm.
In one embodiment, the channel 111 is a microchannel that corresponds in size to a nozzle of an underfill dispenser. Electrical coupling for the interposer 112 is accomplished through bond pads 114 that are landed on a mounting substrate 116. The bond pads 114 correspond to the bumps 110. A die 120, such as a semiconductive die, includes bond pads 120A.
In one embodiment, as shown in
Capillary conditions cause a wicking action assisting flow of underfill mixture into the region between the interposer 112 and the mounting substrate 116. Capillary flow is the action by which a liquid is drawn towards a solid surface, such as electrical bumps and substrates, because there is a stronger attraction or adhesion between the liquid molecules and the surface particles, than between the liquid molecules themselves. In this embodiment, the liquid underfill material wicks its way through the solder joints and between adjacent surfaces (of the interposer and mounting substrate) until the underfill is complete.
The effectiveness of an underfill mixture or composite depends on its chemical, physical, and mechanical properties. In one embodiment, properties that make an underfill mixture desirable include low CTE, low moisture uptake, high adhesion, high toughness, high glass transition (Tg) temperature, high heat distortion temperature, and others. Capillary conditions that facilitate wicking of the underfill material between two surfaces include the viscosity of the underfill material, the distance between the solid surfaces through which the underfill material flows, the pressure in the spaces to be filled with underfill material, the pressure forcing the underfill material into the spaces, and other conditions.
In this embodiment, the viscosity of the underfill mixture 122 is in a range between 0.5 Pas and 9.0 Pas. In one embodiment, the pressure in the spaces to be filled with underfill material is atmospheric or negative pressure, such as a vacuum draw. In one embodiment, there is a pressure forcing the underfill material into the spaces to be filled.
In one embodiment, the distance between the adjacent surfaces of the interposer and the mounting substrate and the distance between adjacent bumps (or joints) are in a range from about 150 um to about 280 um. In some embodiments, where the distance is less than this range, flow around the electrical bumps may be hindered by the increasingly smaller pitch and/or the increasingly smaller spacing between the substrates. In embodiments where the distance between the substrates and the distance between adjacent bumps exceed this range, flow process may be also be hindered.
The solder joints 118 are reinforced by filling a gap or space between the interposer and mounting substrate, and by filling around the joints, with the underfill mixture 122. In one embodiment, this underfill mixture 122 reduces joint failures due to stress during thermal cycling. In one embodiment, the underfill mixture 122 acts as a CTE intermediary for mismatched CTEs of the interposer and mounting substrate. In one embodiment, the interposer underfill mixture 122 substantially completely fills the volume between interposer 112 and substrate 116 so that the mixture 122 supports and protects the adjacent interposer and substrate at least in the die shadow region.
In one embodiment, capillary underfilling can be assisted by pumping the underfill composite between the substrates, or by vacuum-assisted drawing of the underfill composite between the substrates. The underfill mixture 122 between the interposer 112 and the substrate 116, according to various embodiments, will be described below in greater detail. In another embodiment, the no-flow underfill process, discussed later, is used to dispense the underfill mixture 122 between the interposer and the mounting substrate.
In one embodiment, the fillet mixture is the same as the underfill mixture. In an additional embodiment, the fillet and underfill mixtures are dispensed at different times to optimize flow and reduce risk for entrapped air. In one embodiment, the underfill mixture material is optimized for flow and adhesion. In some embodiments the fillet material may be optimized to allow for increased fracture strength, adhesion, or crack mitigation. In one embodiment, the fillet mixture does not have to flow a tight gap or fine pitch, but does experience the highest stresses. In this embodiment, the fillet mixture is a “tougher” material compared to the underfill mixture at the expense of reduced flow or increased viscosity.
The microchannel 111 is shown as a rectangular slot in the embodiment of
A curing process is carried out to achieve the package assembly 134. The curing process is carried out according to specific embodiments. In one embodiment, curing the mixture is done by an autocatalytic process. The autocatalytic process is carried out in one embodiment by providing a reactive diluent in the underfill and fillet mixtures 122, 126, 132. In another embodiment, the curing process is carried out by an additive catalytic curing process. The additive catalytic curing process includes an additive such as a metal catalyst powder that causes the fillet and/or underfill mixtures to cure. In another embodiment, a cross-linking/hardening process is carried out to cure the underfill and/or fillet mixtures. Examples of specific cross-linker/hardener composition are set forth herein. In another embodiment, a thermoset curing process is carried out. Typically, several curing process embodiments are assisted by thermal treatment. However, in some embodiments, such as the use of a liquid crystal thermoset monomer, thermoset processing may be done without other curing agent processes.
In one embodiment, as shown in
Capillary conditions cause a wicking action assisting flow of the underfill mixture into the region between the interposer 212 and the mounting substrate 216. In one embodiment, the interposer underfill mixture 222 substantially completely fills the volume between interposer 212 and substrate 216 so that the mixture 222 supports and protects the adjacent interposer and substrate at least in the die shadow region. While the underfill is being flowed in the gap between the interposer and the substrate, the vent hole 211 facilitates the speed of the underfill flow. The vent hole 211 allows air to escape or vent up and out of that gap which removes potentially trapped air and facilitates capillary flow up into the vent hole itself. The speed of the underfill flow is thereby increased.
As shown in
A curing process of underfill and fillet mixtures 222, 226, 232 is carried out to achieve the package assembly 234 in a manner similar to that as described with respect to
In one embodiment, the interposer 312 has a channel 311a that extends through a channel body from a front side 312a through to a back side 312b of the interposer 312. In one embodiment, the channel 311a corresponds to the vent hole 211 described above. In this embodiment, the interposer 312 further has a micro channel 311b, corresponding to the microchannel 111 described above.
Between the interposer 312 and the substrate 316, and between the solderballs 319, is interposer underfill mixture 322. The underfill mixture 322 is dispensed through the microchannel 311b and capillary conditions cause a wicking action assisting flow of the underfill mixture 322 into the region between the interposer 312 and the mounting substrate 316.
In this embodiment, the channel 311a is a vent hole that lies within the die shadow region. In embodiments, the vent hole 311a may be substantially centered in the interposer, in the midst of the reflowed solder bumps 318, or anywhere in the die shadow region. In the embodiment shown, the reflowed solder bumps 318 and bond pads 314 are within the die shadow region. In one embodiment, the die shadow region extends from four exterior edges of the die towards the substrate 316.
While the underfill is being flowed in a gap between the interposer and the substrate, the vent hole 311a allows air to escape and vent up and out of that gap, thereby increasing the speed of the underfill flow. As shown in
In an additional embodiment, instead of a die underfill dispenser 128 and 228, a no-flow underfill process is used. However, if a vent hole 211, 311a is used for allowing air to escape from under the interposer, the no-flow underfill process occurs after the interposer underfill is dispensed. If there is only a microchannel 111, 311b, and no vent hole, the no-flow underfill process may occur before or after the interposer underfill is dispensed. A no-flow underfill mixture may be applied either to the die or to the front side of the interposer. Next, the die and the interposer are aligned and brought together to form an assembly. The no-flow underfill mixture is cured, and the solder bump(s) are reflowed.
In one embodiment, the no-flow underfill process uses a no-flow underfill mixture that reduces the bump interconnection yield, because the filler gets deposited between the bumps and the pads such that electrical connections are not achieved.
According to an embodiment, the solder bumps 110 and 210 include substantially Pb-free solder technology. In another embodiment, the solder bumps 110 and 210 are Pb-containing solder. By “substantially Pb-free solder”, it is meant that the solder is not designed with Pb content according to industry trends.
One embodiment relates to achieving an underfill mixture that includes physical properties of the previously known underfill composites that included inorganic particles. In one embodiment, underfill composites have coefficients of thermal expansion (CTEs) that are between the CTEs of the chip and the board. Accordingly, some embodiments include underfill mixtures that have a range of compositions and combinations.
Some desirable properties of underfill mixtures include a high modulus, low viscosity at the time of dispensing onto a chip (or die) and/or substrate, low CTE and good adhesion to the interfaces post cure, so that no delamination at the interface occurs during device testing and field use. Some other desirable properties of underfill mixtures include a high glass-transition (Tg) temperature, and a low moisture uptake.
According to various embodiments, the principal underfill compositions include at least one of silesquioxanes, thermosetting liquid crystal monomers, and mixtures thereof.
Additive materials are included with the principal underfill compositions. The additive materials and the principal underfill compositions constitute “underfill mixtures” according to embodiments set forth herein.
One additive material according to an embodiment is an elastomer for imparting flexibility to the principal underfill composition. Another additive material according to an embodiment is a hardener/crosslinker. The specific hardener/crosslinker that is employed will depend upon compatibility with the principal underfill composition. Hardeners/crosslinkers can be both aromatic and aliphatic in nature. The hardener/crosslinker in one embodiment is an anhydride composition. In another embodiment, the hardener/crosslinker is an amine.
Another additive material according to an embodiment is a catalyst. Another additive material according to an embodiment is a reactive diluent. Another additive material according to an embodiment is an adhesion promoter. Another additive material according to an embodiment is a flow modifier such as a surfactant. Another additive material according to an embodiment is a deforming agent. Another additive material according to an embodiment is a fluxing agent. Another additive material according to an embodiment is a toughening agent. A toughening agent causes the underfill mixture to resist crack propagation. Another additive material according to an embodiment is an inorganic filler. The specific characteristics and composition of the underfill or fillet mixture that is employed will depend upon compatibility with the principal underfill or fillet composition.
It will be readily understood to those skilled in the art that various other changes in the details, material, and arrangements of the parts and method stages which have been described and illustrated in order to explain the nature of this invention may be made without departing from the principles and scope of the invention as expressed in the subjoined claims.
Although the inventive concept may be discussed in the exemplary context of an interposer of a package, the claims are not so limited. Indeed, embodiments of the present invention may well be implemented as part of any package system. The described packages can also be implemented in a number of different embodiments, including an electronic system and a computer system. The elements, materials, geometries, dimensions, and sequence of operations can all be varied to suit particular packaging requirements.
The packaging techniques described herein may be used with a die as described above, or with flash memory, SRAM, and PsuedoSRAM combinations. Therefore, such die packages could be part of system memory as well.
In one embodiment, a package includes a die including an active surface, a substrate electrically coupled with the active surface, and an interposer between the die and the substrate. The interposer has a body with a first surface, an opposite second surface, and a channel passing through the body from the first surface to the second surface.
In one embodiment, a packaging system includes a die, a substrate electrically coupled with the die, an interposer between the die and the substrate, and underfill mixture dispensed between the interposer and the substrate using capillary flow. The interposer has a body with a first surface, an opposite second, surface, and a channel passing through the body from the first surface to the second surface.
In one embodiment, a process includes forming a channel through a channel body from a first surface of an interposer through to an opposite second surface of the interposer, disposing the interposer between a die and a substrate, and dispensing underfill between the interposer and the substrate. The channel is at least one of a vent hole to facilitate capillary flow of the underfill mixture, and a microchannel through which the underfill mixture is dispensed.
It is emphasized that the Abstract is provided to comply with 37 C.F.R. §1.72(b) requiring an Abstract that will allow the reader to quickly ascertain the nature and gist of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.
In the foregoing Detailed Description, various features are grouped together in a single embodiment for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claimed embodiments of the invention require more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive subject matter lies in less than all features of a single disclosed embodiment. Thus the following claims are hereby incorporated into the Detailed Description of Embodiments of the Invention, with each claim standing on its own as a separate preferred embodiment.
