The present invention is in the field of semiconductor packaging and is more specifically directed to package with heat transfer.
Modern semiconductor packages continue to become smaller due to improvements in fabrication technology. Yet these smaller packages are more densely packed with circuitry and components that often run much faster than their predecessors. These improvements typically increase the amount of heat generated within the package, while reducing the amount of exterior surface area available for the dissipation of heat. The factors of small size and high speed circuitry contribute to certain undesirable conditions for the operation of modern packages. For instance, semiconductor performance and reliability are directly related to the operating temperature interior and exterior to the package, and thus performance and reliability are also related to the ability to dissipate heat, from the package.
Conventionally, heat reduction is achieved by the inclusion of additional interior and/or exterior heat sinks that undesirably affect the overall form factor of the package. However, as mentioned above, with modern packages, the interior space within the package, or the exterior space for the placement of the package, or both, are often heavily constrained. For example, in small form factor applications such as mobile technology, the overall form factor of a mobile device is so small that there are both profile or height constraints, as well as board surface area constraints, for the onboard electronics.
A semiconductor package includes an encapsulant, a semiconductor die within the encapsulant, and a terminal for electrically coupling the semiconductor die to a node exterior to the package. The package further includes solder coupling the semiconductor die to the terminal. The semiconductor package is configured to dissipate heat through a top surface of the package. To directly dissipate heat via the top surface of the package, a portion of the semiconductor die is preferably exposed at the top surface of the package.
Alternatively, a package for a semiconductor device includes the semiconductor device, and one or more terminals coupled to the semiconductor device. A portion of one or more of the terminals is exposed at a surface of the package. Instead of having a semiconductor device or die directly exposed at a surface of the package, a thermal cushion is coupled to the semiconductor device. The thermal cushion is formed by using a thermally conductive epoxy, that is preferably located near the top surface of the package. A molding compound encapsulates the semiconductor device.
Typically, the epoxy is exposed at an exterior of the package, and is preferably of the thermally conductive type. In some packages, the epoxy has a width dimension that approximates the dimensions of a surface of the package. Alternatively, the epoxy has a width dimension that is less than the dimensions of a surface of the package such as, for instance, the width of the die. The terminal is coupled to the semiconductor device by using solder, which has a variety of shapes, including solder balls and/or pillars, for example.
Alternatively, or in conjunction with the thermal epoxy, the package of some embodiments includes a cap coupled to the semiconductor device. Typically, the cap is coupled to the semiconductor device by using thermally conductive epoxy. The cap is generally formed by using a thermally conductive material, such as a metal, for example. The cap has a dimension that approximates a dimension of an exterior surface of the package, or alternatively, the cap has a dimension that is less than an exterior dimension of the package. Typically, the epoxy forms a layer that is approximately the width of the cap, or the epoxy forms a layer that is approximately the width of the semiconductor device.
In some implementations, the cap has a dimension that varies from the interior to the exterior of the package. For instance, where the cap comprises a step, a smaller portion of the cap faces the interior of the package, while a larger portion of the cap faces the exterior of the package to aid in heat dispersion. As another example, the cap has a tapered shape that broadens toward the exterior surface of the package. In some cases, the cap comprises an interlocking feature that is formed by using a step and/or a tapered shape. Preferably, in these cases, the smaller portion of the cap is located near the exterior of the package, while the larger portion is located near the interior of the package.
The novel features of the invention are set forth in the appended claims. However, for purpose of explanation, several embodiments of the invention are set forth in the following figures.
In the following description, numerous details and alternatives are set forth for purpose of explanation. However, one of ordinary skill in the art will realize that the invention can be practiced without the use of these specific details. In other instances, well-known structures and devices are shown in block diagram form in order not to obscure the description of the invention with unnecessary detail.
In a particular embodiment of the invention, a package is configured to dissipate heat during operation via a bottom side and/or a top side of the package. For packages that dissipate heat from a bottom side, solder balls bring the heat from the semiconductor die through the metal terminals and/or through the exposed die attach pads to the printed circuit board (PCB). Alternatively, pillar bumps, rather than solder balls, transfer heat from the die through the metal terminals and/or exposed die attach pads to the printed circuit board.
For packages that dissipate heat from a top side, at least one side of the die is exposed to the outside environment. Hence, in these packages, heat transfer is achieved via the die body itself.
In certain instances, it is preferable that the semiconductor device is not directly exposed at the exterior of the package. Hence, alternatively, the semiconductor device is coupled to another structure that is exposed at one or more surface of the package. For instance, the additional structure includes a thermally conductive layer, which has one side exposed to the outside environment. The thermally conductive layer is typically formed by using conductive epoxy or a metal cap.
Some of the packages that employ heat transfer via a thermal conductive layer at the top of the package, use a thermal epoxy that has shock and/or force absorbing properties. In these packages, the thermal conductive layer not only helps to transfer heat from the semiconductor die to the outside environment, but also serves as a cushion to absorb impact to the die. Such impact often occurs during mold cavity clamp of the molding process.
According to some packages of the invention heat transfer is advantageously achieved by two routes, such as via a thermal conductive layer on top, and also via a bottom exposed pad. In these packages, the exposed die attach pad at the bottom of the package encourages efficient heat transfer to the printed circuit board, while the thermal conductive layer has a variety of applications at the top surface of the package. For instance, the top layer of some embodiments advantageously provides for coupling to another structure and/or node external to the top surface of the package.
Alternatively, or in conjunction with an epoxy type material, the thermal conductive layer at the top of the package is formed by using a metal cap. The metal material is selected, at least in part, based on its ability to enhance the dissipation of heat. Further, the top exposed thermal conductive layer of various embodiments is formed into a variety of advantageous shapes. For instance, the die of some packages are small. Hence, the ability of these small die to transfer heat through a bottom exposed pad is limited. However, for these cases, a heat conductive layer is preferably added near the top of the package, to advantageously disperse and/or transfer heat toward the top surface of the package. The top conductive layer is preferably formed by using an epoxy and/or a metal cap that is advantageously malleable to meet the particular size and/or shape requirements for the smaller die. Moreover, it is often advantageous that the top exposed thermal layer itself has a small or other particular shape. Further, the various shapes and sizes of the top exposed thermal layer are combined with one or more bottom exposed features such as a die attach pad, for increased and/or maximized thermal transfer. Examples of certain embodiments of the invention are further described below, by reference to the figures.
Top Exposed Layer
Embodiments employing a top exposed layer and/or a thermal cushion are further described in relation to
The semiconductor device 104A is preferably electrically coupled to one or more terminals 106A by using a bonding means 108A. One of ordinary skill recognizes a variety of bonding means such as, for example, solder balls, pillar bumps, and/or bonding wires. However, the bonding means is advantageously selected for the ability to transfer heat. Preferably, the layer 110A is formed by using a thermally conductive epoxy such as AbleStick 84-3. The layer 110A of these embodiments advantageously receives heat from the semiconductor device 104A and transfers the heat to a location that is external to the package 100A.
Metal Cap
Metal Cap for Small Die
More specifically,
Exposed Pad
Small Metal Cap
Small Metal Cap and Exposed Die Pad
Method
After the cushion and/or the cap are formed and/or placed at the step 2140, the process 2100 transitions to the step 2150, where a molding compound is used to encapsulate the package. Preferably, the encapsulation at the step 2150 leaves a bottom surface of the contact terminal(s) and/or attach pad(s) exposed at the exterior of the package. Further preferably, the encapsulation leaves a top surface of the thermal transfer layer, such as the thermally conductive cushion and/or the cap, exposed at an exterior of the package. The step 2150 of some embodiments alternatively includes additional steps such as singulation, etching, and/or stamping or other means to leave the selected thermally and/or electrically conductive elements of the package exposed at the exterior surfaces.
While the invention has been described with reference to numerous specific details, one of ordinary skill in the art will recognize that the invention can be embodied in other specific forms without departing from the spirit of the invention. Thus, one of ordinary skill in the art will understand that the invention is not to be limited by the foregoing illustrative details, but rather is to be defined by the appended claims.
This application claims benefit of priority under 35 U.S.C. section 119(e) of U.S. Provisional Patent Application 60/847,434 filed Sep. 26, 2006, which is incorporated herein by reference.
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