LEADLESS SEMICONDUCTOR PACKAGE AND METHOD OF MANUFACTURE
A leadless semiconductor package includes a package body on a leadframe that includes a die paddle and a plurality of bond pads, none of which extend as far as a lateral face of the body. During manufacture of the package, molding compound is deposited over a face of the leadframe on which the die paddle and bond pads are positioned. After the molding compound is cured, a back side of the leadframe is etched to isolate the die paddle and bond pads, back surfaces of which remain exposed at a back face of the body. During manufacture of the leadframe, a parent substrate is etched to define the die paddle and a plurality of bond pads on one side of the substrate and a plurality of cavities on the opposite face.
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1. Technical Field
The present disclosure relates to semiconductor packaging, and in particular to leadframe-based packages, to leadframes employed in such packages, and most particularly to flat, leadless type packages and leadframes, such as, e.g., QFN packages.
2. Description of the Related Art
While significant advances have been made in semiconductor packaging, including the development of a very large number of packaging types, the majority of semiconductor devices still employ leadframe based packages. This is due to a number of reasons. In particular, leadframe packages are relatively inexpensive to produce, are well known and understood, the tooling is already in hand or readily available, etc. Additionally, leadframe packages have some advantages over many other packages, including having better thermal transmission characteristics, and more being more robust. As industry demand moves toward smaller packages and higher contact density, leadframe technology continues to evolve, so that even within the general category of leadframe packages, there are many different types. However, leadframe-based packages have at least one element in common: they all have a leadframe. Leadframes are usually stamped or chemically milled from thin metal strips, which are generally formed in rolls. Typically, a leadframe includes a die paddle on which a semiconductor die is mounted, and a plurality of contact pads that are placed in electrical contact with respective bond pads of the leadframe.
Leadframes are machined from a roll, i.e., strip, of metal foil, usually copper, which can be plated to prevent oxidation that might otherwise interfere with making good electrical contact. Chemical milling is typically used to form leadframes that have very fine details, such as with near chip-scale frames and frames that employ a large number of leads.
There is continual industry pressure to reduce the thickness of semiconductor packages, especially for use in consumer electronic devices such as cell phones and PDA devices. In some cases, OEM manufacturers require that a package height be no more than 400 μm, and it is likely that even thinner packages will be required in the future. One problem associated with leadframe-based packages is that there is a minimum thickness requirement for leadframe material. Typically, leadframe strips cannot be much less than about 100 μm, because thinner material becomes virtually impossible to handle without damage. It lacks the strength and rigidity to withstand normal handling and the processes to which it is subjected during typical manufacturing operations. To the extent that special tooling and procedures could be devised to successfully handle thinner material, this would represent a significant additional expense and would eliminate one of the primary advantages of leadframes over other packaging formats, i.e., the ability of many existing automated systems to perform some or all of the processing steps required for more advanced package designs.
According to one embodiment, a leadless semiconductor package is provided, including a package body on a leadframe that includes a die paddle and a plurality of bond pads, all of which have a back surface exposed at the back side of the body, but none of which extend as far as a lateral face of the body. The die paddle and bond pads can be plated, on their respective front faces and/or back faces, with a protective metal layer.
During manufacture of the package, molding compound is deposited over a front face of the leadframe on which the die paddle and bond pads are positioned. The face of the leadframe is substantially continuous and without perforations for at least the lateral dimensions of the body. After the molding compound is cured, a back side of the leadframe is etched to isolate the die paddle and bond pads, back surfaces of which remain exposed at a back face of the body after the etching.
During manufacture of the leadframe, a parent substrate is etched on a first face to define elements of the leadframe such as, e.g., the die paddle and the plurality of bond pads. The substrate is also etched on a second face, opposite the first face, to define a plurality of cavities on the second face, each positioned directly opposite a corresponding one of the elements on the first face, and each sized and shaped to substantially match the size and shape of the corresponding element. A protective metal layer is plated onto the surfaces of the elements of the lead frame and onto an inner wall of each of the cavities. The layer of metal plated onto the inner wall of each of the cavities acts as an etch stop to protect the corresponding element during the etch performed as part of the packaging process.
Turning now to
It can be seen, with reference to
The specific elements shown in
Turning now to
The metal used to plate the elements of the leadframe can be any appropriate formulation, but is preferably resistant to oxidation and corrosion, in order to provide a reliable contact surface for the wirebonding process. According to one embodiment, the plating includes a layer of nickel, a layer of palladium, and a layer of gold. Total thickness of the plating will usually not exceed about 5 μm, and is preferably less than about 2 μm. Most of that thickness is made up of the nickel layer, with the layers of palladium and gold being relatively much thinner.
The metal plated in the cavities on the back side can be the same metals, or can be different metals. During the packaging process, the plated metal in the cavities will be used as an etch resist, then later during assembly of an electronic device that incorporates the completed package, the same metal will form contact surfaces for establishing electrical contact between the semiconductor die and contacts of a circuit board.
Generically, leadframe features formed in the manner described above can be referred to as lands, while the surrounding surface can be referred to as the lower face. This is not to be confused with the back side or back face of the substrate, which is on the opposite side from the lands. The lower face 39 is part of the front face of the substrate 62.
A process for manufacturing the leadframe 60, according to one embodiment, will be described in more detail with reference to
As shown in
Following the etch step, the back side of the substrate is plated. In an electroplating operation, the material to be plated must be electrically conductive. Because the back side of the strip 64 is entirely covered by a layer of non-conductive etch resist except over the newly formed cavities 32, 34, and 36, only the inner walls of the cavities are plated in the operation. If necessary, the front side of the strip can be temporarily covered to prevent plating on that side. Finally, the etch resist layers on both sides of the strip 64 are removed from the strip, leaving the completed leadframe, shown in close detail in
While the cavities are disclosed as being slightly smaller than the corresponding feature on the opposite face of the substrate, according to an alternative embodiment, the cavities can be identical in size and shape to the corresponding feature. in such an embodiment, the etch step is controlled to be terminated before the etch process extends half the total thickness from each side. instead, the process is controlled to terminate when between about 5%-10% of the thickness remains between the etches. In this way, a supporting structure similar to the web 72 will remain between the cavities and the lower face 39. One advantage to this embodiment is that the masks used to form the resist layers 66 and 68 can be mirror images of each other, which is simpler and less expensive to produce than a mask with features that are sized differently. In some cases it may even be possible to use the same mask on both sides. Of course, it would be necessary to use a negative-acting photoresist on one side, and a positive acting resist on the other.
First, as shown in
Moving to
Once the etching process is complete, the portions of the plating that were on the sidewalls of the cavities will be unsupported, as shown in the detail of
Finally, as shown in
It will be recalled that in the first etch process, described with reference to
It should be born in mind, for example, that at any given point, the substrate of the leadframe 60 of
As previously mentioned, a leadframe configured according to the principles disclosed above is not limited by the need to have all the elements coupled to a support frame. Instead, of being supported by a frame that lies in the same plane as the elements, but outside the finished dimensions of a putative package, the elements of the various embodiments are supported from structure that is much closer, lying a plane that defines a face of the intended package. One resulting distinction is that, unless there is a practical and beneficial reason, a semiconductor package formed in accordance with an embodiment will not have any portion of the original leadframe visible or exposed around its lateral perimeter. This is in contrast to most leadframe-based devises, including the one described in the background with reference to
While a particular series of process steps has been disclosed for manufacturing a leadframe, there are many different known processes related to patterning and etching, many of which are interchangeable and can be selected, often merely on the basis of preference. Thus, an endless variety of different ways can be devised for producing, for example, the leadframe of
Additionally, while the preferred method of manufacture is by chemical machining, the substrate of a leadframe can also be stamped to form lands on the front face and corresponding cavities on the back face. The parent sheet is plated on both faces prior to being stamped, and the back side is also coated with an etch resist. The back side is subjected to a brief abrasion after stamping, which removes the plating and resist on the back surface, without removing them from the cavities. After the molding compound is deposited and cured, and the back of the leadframe is etched, the process will proceed as described above, except that the plating on the front face will remain. It is then necessary to perform another etch to remove the plating, while the plating in the cavities will be largely protected by the etch resist remaining in the cavities, although the burrs extending around the sidewalls of the cavities will be removed as well, eliminating the need for the pressure washing step. Following the etch process, the etch resist is removed using the appropriate solvents.
As used in the specification and claims, the term front is used to refer to the side of a leadframe that would face away from a circuit board if the leadframe were in a package mounted to the circuit board according to its design. Conversely, back is used to refer to the side or face opposite the front side and facing the circuit board. Use of front and back with reference to other related elements are to be construed accordingly.
The term land is used to refer to the features of a leadframe that extend above the surrounding surface on the front face, and the term lower face is used to refer to a part of the front face of a leadframe that extends around the lands but lies closer to the back face.
The term lateral is used to refer to directions or dimensions extending in a plane that lies substantially parallel to the front and back faces of a leadframe.
The term coupled, as used in the claims, includes within its scope indirect coupling, such as when two elements are coupled with one or more intervening elements even where no intervening elements are recited. For example, where a claim recites a fluid output of a first heat exchanger coupled to a fluid input of a second heat exchanger, this language also reads on embodiments in which fluid passes from a first heat exchanger through a turbine before entering a second heat exchanger.
The term over is used in the specification and claims to refer to the relative positions of two or more elements with respect to a third element, although the third element may be implied by the context. The term on is used to refer to a physical relationship between two elements. Neither term should be construed as requiring direct physical contact between the elements, nor should they be construed as indicating any particular orientation, either absolute, or with respect to the third element. So, for example, if a claim recites a second layer positioned over a first layer on a substrate, this phrase indicates that the second layer is coupled to the substrate and that the first layer is between the second layer and the substrate. It does not indicate that the layers are necessarily in direct physical contact with each other or with the substrate, but may instead have one or more intervening layers or structures. It also does not indicate that the substrate is oriented in a manner that places the second layer physically above the first layer, nor that, for example, the layers are positioned over a front face of the substrate, as that term is used herein.
In describing the embodiments illustrated in the drawings, directional references, such as right, left, top, bottom, etc., are used to refer to elements or movements as they are shown in the figures. Such terms are used to simplify the description and are not to be construed as limiting the claims in any way.
The unit symbol “μm” is used herein to refer to a value in microns. One micron is equal to 1×10−6 meters.
Ordinal numbers, e.g., first, second, third, etc., are used according to conventional practice, i.e., for the purpose of clearly distinguishing between claimed elements or features thereof. The use of such numbers does not suggest any other relationship, e.g., order of operation or relative position of such elements, nor does it exclude the possible combination of the listed elements into a single, multiple-function, structure or housing. Furthermore, ordinal numbers used in the claims have no specific correspondence to those used in the specification to refer to elements of disclosed embodiments on which those claims read.
Where a claim limitation recites a structure as an object of the limitation, that structure itself is not an element of the claim, but is a modifier of the subject. For example, in a limitation that recites “a leadframe having a die paddle configured to receive a semiconductor die,” the semiconductor die is not an element of the claim, but instead serves to define the scope of the term die paddle. Additionally, subsequent limitations in the same claim or dependent claims that recite or characterize additional elements relative to the semiconductor die do not render the die an element of that claim.
The abstract of the present disclosure is provided as a brief outline of some of the principles of the invention according to one embodiment, and is not intended as a complete or definitive description of any embodiment thereof, nor should it be relied upon to define terms used in the specification or claims. The abstract does not limit the scope of the claims.
The U.S. patent application, Attorney Docket No. 850063.664, filed concurrently herewith and by the same inventors, is directed to subject matter that is related to or has some technical overlap with the subject matter of the present disclosure, and is incorporated herein in its entirety.
Elements of the various embodiments described above can be combined, and further modifications can be made, to provide further embodiments without deviating from the spirit and scope of the invention. Aspects of the embodiments can be modified, if necessary to employ concepts of the various patents, applications and publications to provide yet further embodiments.
These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
Claims
1. A semiconductor package, comprising:
- a package body;
- a die paddle of a first metal, with a layer of a second metal, different from the first metal, positioned on a front surface of the die paddle and a layer of a third metal, different from the first metal, positioned on a back surface of the die paddle, the die paddle positioned in the body so that the back surface of the die paddle is exposed at a back surface of the body;
- a semiconductor die affixed to the front surface of the die paddle over the first layer and encapsulated within the body; and
- a plurality of bond pads of the first metal, each having a layer of the second metal positioned on a respective front surface and a layer of the third metal positioned on a respective back surface, each being encapsulated within the body with a respective back surface exposed at the back surface of the body, and no portion exposed at a lateral face of the body.
2. The package of claim 1 wherein the die paddle and each of the plurality of bond pads are thinner than about 100 microns.
3. The package of claim 1 wherein the die paddle and each of the plurality of bond pads are thinner than about 50 microns.
4. The package of claim 1 wherein the die paddle and each of the plurality of bond pads are between about 10 microns and about 80 microns.
5. The package of claim 1, comprising a contact ring of the first metal, lying in a common plane with the die paddle and positioned to encircle the die paddle, and having a back surface exposed at the back surface of the body.
6. The package of claim 1 wherein the second and third metals are a same metal.
7. A leadframe for a semiconductor package, comprising:
- a substrate of a first metal, having first and second surfaces and extending laterally without substantial perforations over a first area;
- a plurality of lands coupled to the substrate on the first surface entirely within the first area; and
- a plurality of cavities formed in the second surface of the substrate without extending through the substrate, each in a position opposite a respective one of the plurality of lands.
8. The leadframe of claim 7 wherein each of the plurality of cavities has lateral dimensions that are less than corresponding lateral dimensions of the corresponding land opposite.
9. The leadframe of claim 7 wherein a depth of each of the plurality of cavities is approximately equal to a height of each of the plurality of lands above the first surface.
10. The leadframe of claim 7 wherein each of the plurality of lands has a face on which a layer of a second metal is deposited.
11. The leadframe of claim 7 wherein each of the plurality of cavities has an inner wall on which a layer of a second metal is deposited.
12. The leadframe of claim 7 wherein one of the plurality of lands is a die paddle, and others of the plurality of lands are bond pads.
13. A method, comprising:
- etching a first depth into a first face of a substrate and forming thereby a plurality of lands of a leadframe, the first depth being less than an initial thickness of the substrate; and
- etching a plurality of cavities a second depth into a second face of the substrate, each positioned opposite a respective one of the lands, the second depth being less than the initial thickness of the substrate.
14. The method of claim 13, comprising plating a layer of metal over the first face of the substrate.
15. The method of claim 14, comprising defining lateral dimensions of each of the plurality of lands by patterning the layer of metal.
16. The method of claim 13, comprising plating a layer of metal on an inner surface of each of the plurality of cavities.
17. The method of claim 13, comprising defining, among the lands of the leadframe, a die paddle and a plurality of bond pads.
18. A method, comprising:
- affixing a semiconductor die to a first surface of a leadframe;
- placing contact pads of the die in electrical contact with corresponding bond pads of the leadframe;
- depositing a molding compound over the semiconductor die on the first surface of the leadframe;
- curing the molding compound on the first surface of the leadframe; and
- exposing portions of a surface of the cured molding compound by removing corresponding portions of the leadframe, while leaving portions of the leadframe embedded in the molding compound.
19. The method of claim 18 wherein the removing comprises etching a second surface of the leadframe, opposite the first surface.
20. The method of claim 18 wherein the leaving comprises selectively etching the second surface of the leadframe without etching portions of the second surface over which a metallic layer is deposited.
21. The method of claim 18 wherein the placing comprises placing contact pads of the die in electrical contact with bond pads that are positioned on the first surface of the leadframe substantially opposite corresponding portions of the second surface over which a metallic layer is deposited.
22. The method of claim 18 wherein the affixing comprises affixing the semiconductor die to a die paddle that is positioned on the first surface of the leadframe.
Type: Application
Filed: Dec 30, 2010
Publication Date: Jul 5, 2012
Applicant: STMICROELECTRONICS, INC. (Calamba City)
Inventors: Jerry Tan (Calamba City), William Cabreros (Calamba City)
Application Number: 12/982,743
International Classification: H01L 23/495 (20060101); H01L 21/64 (20060101); H01L 21/60 (20060101);