INTERPOSER FRAME WITH POLYMER MATRIX AND METHODS OF FABRICATION

Abstract

An array of chip sockets defined by an organic matrix framework surrounding sockets through the organic matrix framework and further comprising a grid of metal vias through the organic matrix framework. In an embodiment, a panel includes an array of chip sockets, each surrounded and defined by an organic matrix framework including a grid of copper vias through the organic matrix framework. The panel includes at least a first region with sockets having a set of dimensions for receiving one type of chip and a second region with sockets and another set of dimensions for receiving a second type of chip.

Description

RELATED APPLICATIONS

This patent application is a continuation-in-part of U.S. patent application Ser. No. 14/249,282, titled “Method for Fabricating Embedded Chips,” that was filed on Apr. 9, 2014. The disclosure of U.S. Ser. No. 14/249,282 is incorporated herein by reference in its entirety.

BACKGROUND

1. Field of the Disclosure

The present invention is directed to chip packaging, specifically to embedded chips.

2. Description of the Related Art

Driven by an ever greater demand for miniaturization of ever more complex electronic components, consumer electronics such as computing and telecommunication devices are becoming ever more integrated. This has created a need for support structures such as IC substrates and IC interposers that have a high density of multiple conductive layers and vias that are electrically insulated from each other by a dielectric material.

The general requirement for such support structures is reliability and appropriate electrical performance, thinness, stiffness, planarity, good heat dissipation and a competitive unit price.

Of the various approaches for achieving these requirements, one widely implemented manufacturing technique that creates interconnecting vias between layers uses lasers to drill holes through the subsequently laid down dielectric substrate through to the latest metal layer for subsequent filling with a metal, usually copper, that is deposited therein by a plating technique. This approach to creating vias is sometimes referred to as ‘drill & fill’, and the vias created thereby may be referred to as ‘drilled & filled vias’.

There are a number of disadvantages with the drilled & filled via approach. Since each via is required to be separately drilled, the throughput rate is limited, and the costs of fabricating sophisticated, multi-via IC substrates and interposers becomes prohibitive. In large arrays it is difficult to produce a high density of high quality vias having different sizes and shapes in close proximity to each other by the drill & fill methodology. Furthermore, laser drilled vias have rough side walls and taper inwards through the thickness of the dielectric material. This tapering reduces the effective diameter of the via. It may also adversely affect the electrical contact to the previous conductive metal layer especially at ultra small via diameters, thereby causing reliability issues. Additionally, the side walls are particularly rough where the dielectric being drilled is a composite material comprising glass or ceramic fibers in a polymer matrix, and this roughness may result in stray inductances.

The filling process of the drilled via holes is usually achieved by copper electroplating. Electroplating into a drilled hole may result in dimpling, where a small crater appears at the end of the via. Alternatively, overfill may result, where a via channel is filled with more copper than it can hold, and a domed upper surface that protrudes over the surrounding material is created. Both dimpling and overfill tend to create difficulties when subsequently stacking vias one on end of the other, as required when fabricating high-density substrates and interposers. Furthermore, it will be appreciated that large via channels are difficult to fill uniformly, especially when they are in proximity to smaller vias within the same interconnecting layer of the interposer or IC substrate design.

The range of acceptable sizes and reliability is improving over time. Nevertheless, the disadvantages described hereinabove are intrinsic to the drill & fill technology and are expected to limit the range of possible via sizes. It will further be noted that laser drilling is best for creating round via channels. Although slot shaped via channels may theoretically be fabricated by laser milling, in practice, the range of geometries that may be fabricated is somewhat limited and vias in a given support structure are typically cylindrical and substantially identical.

Fabrication of vias by drill & fill is expensive and it is difficult to evenly and consistently fill the via channels created thereby with copper using the relatively, cost-effective electroplating process.

Laser drilled vias in composite dielectric materials are practically limited to a minimum diameter of 60×10⁻⁶ m, and even so suffer from significant tapering shape as well as rough side walls due to the nature of the composite material drilled, in consequence of the ablation process involved.

In addition to the other limitations of laser drilling as described hereinabove, there is a further limitation of the drill & fill technology in that it is difficult to create different diameter vias in the same layer, since when drill different sized via channels are drilled and then filled with metal to fabricate different sized vias, the via channels fill up at different rates. Consequently, the typical problems of dimpling or overfill that characterize drill & fill technology are exasperated, since it is impossible to simultaneously optimize deposition techniques for different sized vias.

An alternative solution that overcomes many of the disadvantages of the drill & fill approach, is to fabricate vias by depositing copper or other metal into a pattern created in a photo-resist, using a technology otherwise known as ‘pattern plating’.

In pattern plating, a seed layer is first deposited. Then a layer of photo-resist is deposited thereover and subsequently exposed to create a pattern, and selectively removed to make trenches that expose the seed layer. Via posts are created by depositing Copper into the photo-resist trenches. The remaining photo-resist is then removed, the seed layer is etched away, and a dielectric material that is typically a polymer impregnated glass fiber mat, is laminated thereover and therearound to encase the via posts. Various techniques and processes can then be used to planarize the dielectric material, removing part of it to expose the ends of the via posts to allow conductive connection to ground thereby, for building up the next metal layer thereupon. Subsequent layers of metal conductors and via posts may be deposited there onto by repeating the process to build up a desired multilayer structure.

In an alternative but closely linked technology, known hereinafter as ‘panel plating’, a continuous layer of metal or alloy is deposited onto a substrate. A layer of photo-resist is deposited over an end of the substrate, and a pattern is developed therein. The pattern of developed photo-resist is stripped away, selectively exposing the metal thereunder, which may then be etched away. The undeveloped photo-resist protects the underlying metal from being etched away, and leaves a pattern of upstanding features and vias.

After stripping away the undeveloped photo-resist, a dielectric material, such as a polymer impregnated glass fiber mat, may be laminated around and over the upstanding copper features and/or via posts. After planarizing, subsequent layers of metal conductors and via posts may be deposited there onto by repeating the process to build up a desired multilayer structure.

The via layers created by pattern plating or panel plating methodologies described above are typically known as ‘via posts’ and feature layers from copper.

It will be appreciated that the general thrust of the microelectronic evolution is directed towards fabricating ever smaller, thinner, lighter and more powerful products having high reliability. The use of thick, cored interconnects, prevents ultra-thin products being attainable. To create ever higher densities of structures in the interconnect IC substrate or ‘interposer’, ever more layers of ever smaller connections are required.

If plated, laminated structures are deposited on a copper or other appropriate sacrificial substrate, the substrate may be etched away leaving free standing, coreless laminar structures. Further layers may be deposited on the side previously adhered to the sacrificial substrate, thereby enabling a two sided build up, which minimizes warping and aids the attaining of planarity.

One flexible technology for fabricating high density interconnects is to build up pattern plated or panel plated multilayer structures consisting of metal vias or via post features having various geometrical shapes and forms in a dielectric matrix. The metal may be copper and the dielectric may be a film polymer or a fiber reinforced polymer. Typically a polymer with a high glass transition temperature (T_g) is used, such as polyimide or epoxy, for example. These interconnects may be cored or coreless, and may include cavities for stacking components. They may have odd or even numbers of layers and the vias may have non circular shapes. Enabling technology is described in previous patents issued to Amitec-Advanced Multilayer Interconnect Technologies Ltd.

For example, U.S. Pat. No. 7,682,972 to Hurwitz et al. titled “Advanced multilayer coreless support structures and method for their fabrication” describes a method of fabricating a free standing membrane including a via array in a dielectric, for use as a precursor in the construction of superior electronic support structures. The method includes the steps of fabricating a membrane of conductive vias in a dielectric surround on a sacrificial carrier, and detaching the membrane from the sacrificial carrier to form a free standing laminated array. An electronic substrate based on such a free standing membrane may be formed by thinning and planarizing the laminated array, followed by terminating the vias. This publication is incorporated herein by reference in its entirety.

U.S. Pat. No. 7,669,320 to Hurwitz et al. titled “Coreless cavity substrates for chip packaging and their fabrication” describes a method for fabricating an IC support for supporting a first IC die connected in series with a second IC die; the IC support comprising a stack of alternating layers of copper features and vias in insulating surround, the first IC die being bondable onto the IC support, and the second IC die being bondable within a cavity inside the IC support, wherein the cavity is formed by etching away a copper base and selectively etching away built up copper. This publication is incorporated herein by reference in its entirety.

U.S. Pat. No. 7,635,641 to Hurwitz et al. titled “Integrated circuit support structures and their fabrication” describes a method of fabricating an electronic substrate comprising the steps of; (A) selecting a first base layer; (B) depositing a first etchant resistant barrier layer onto the first base layer; (C) building up a first half stack of alternating conductive layers and insulating layers, the conductive layers being interconnected by vias through the insulating layers; (D) applying a second base layer onto the first half stack; (E) applying a protective coating of photo-resist to the second base layer; (F) etching away the first base layer; (G) removing the protective coating of photo-resist ; (H) removing the first etchant resistant barrier layer; (I) building up a second half stack of alternating conductive layers and insulating layers, the conductive layers being interconnected by vias through the insulating layers, wherein the second half stack has a substantially symmetrical lay up to the first half stack; (J) applying an insulating layer onto the second half stack of alternating conductive layers and insulating layers, (K) removing the second base layer, and (L) terminating the substrate by exposing ends of vias on outer surfaces of the stack and applying terminations thereto. This publication is incorporated herein by reference in its entirety.

The via post technology described in U.S. Pat. No. 7,682,972, U.S. Pat. No. 7,669,320 and U.S. Pat. No. 7,635,641 lends itself to mass production, with very large numbers of vias being simultaneously electroplated. As mentioned above, current drill & fill vias have an effective minimal diameter of about 60 microns. In contradistinction, via post technology using photo resist and electroplating, enables much higher densities of vias to be obtained. Via diameters of as little as 30 micron diameter are possible and various via geometries and shapes could be cofabricated within the same layer.

Over time, it is anticipated that both drill & fill technologies and via post deposition will enable fabrication of substrates with further miniaturization and higher densities of vias and features. Nevertheless, it would appear likely that developments in via post technology will maintain a competitive edge.

Substrates enable chips to interface with other components. Chips have to be bonded to substrates through assembly processes that provide reliable electronic connections to enable electronic communication between chips and substrates.

Embedding chips within the interposers to the outside world enables shrinking the chip package, shortening the connections to the outside world, offers cost savings by simpler manufacturing that eliminates die to substrate assembly processes and potentially has increased reliability.

Essentially, the concept of embedding active components such as analog, digital and MEMS chips involves the construction of chip support structures or substrates, having vias around the chip.

One way of achieving embedded chips is to fabricate chip support structures onto the chip array on the wafer where the circuitry of the support structure is larger than the die unit size. This is known as Fan Out Wafer Layer Packaging (FOWLP). Although the size of silicon wafers is growing, expensive material sets and manufacturing process are still limiting the diameter size to 12″, thereby limiting the number of FOWLP units one can place on the wafer. Despite the fact that 18″ wafers are under consideration, the investment required, materials sets and equipment are still unknown. The limited number of chip support structures that may be processed at one time increases the unit cost of FOWLP, and make it too expensive for markets requiring highly competitive pricing, such as wireless communication, home appliances and automotive markets.

FOWLP also represents a performance limitation since the metal features placed over the silicon wafer as fan-out or fan-in circuitry are limited in thickness to a few microns. This creates electrical resistance challenges.

An alternative fabrication route involves sectioning the wafer to separate the chips and embedding the chips within a panel consisting of dielectric layers with copper interconnects. One advantage of this alternative route is that the panels may be very much larger with very many more chips embedded in a single process. For example, whereas for example, a 12″ wafer enables 2,500 FOWLP chips having dimensions of 5 mm×5 mm to be processed in one go, current panels used the applicant, Zhuhai Access, are 25″×21″, enabling 10,000 chips to be processed in one go. Since the price of processing such panels is significantly cheaper than on wafer processing, and since to throughput per panel is 4× higher than throughput on wafer, the unit cost can drop significantly, thereby opening new markets.

In both technologies, the line spacing and the width of the tracks used in industry are shrinking over time, with 15 micron going down to 10 microns being standard on panels and 5 microns going down to 2 microns on wafers.

The advantages of embedding are many. First level assembly costs, such as wire bonding, flip chip or SMD (Surface Mount Devices) soldering, are eliminated. The electrical performance is improved since the die and substrate are seamlessly connected within a single product. The packaged dies are thinner, giving an improved form factor, and the upper surface of the embedded die package is freed up for other uses including stacked die and PoP (Package on Package) technologies.

In both FOWLP and Panel based embedded die technologies, the chips are packaged as an array (on wafer or panel), and, once fabricated, are separated by dicing.

Embodiments of the present invention address fabricating embedded chip packages.

Embodiments of the present invention address polymer frames with sockets for chips, for packaging chips.

BRIEF SUMMARY

A first aspect is directed to providing an array of chip sockets defined by a framework comprising a polymer matrix and an array of metal vias through the polymer matrix framework.

Typically, each chip socket is surrounded with a frame of polymer matrix comprising copper vias through the framework.

Typically, the framework further comprises glass fiber reinforcements within the polymer matrix.

In some embodiments, the metal vias are via posts.

In some embodiments, each via is in the range of 25 micron to 500 micron wide.

In some embodiments, the grid of metal vias through the organic matrix framework comprises a plurality of via layers.

In some embodiments, a frame around at least one socket comprises a continuous coil of elongated vias posts.

In some embodiments, the continuous coil of elongated vias posts spans a plurality of layers.

In some embodiments, each via is cylindrical and has a diameter in the range of 25 micron to 500 micron.

In some embodiments, adjacent chip sockets have different dimensions.

In some embodiments, adjacent chip sockets have different sizes.

In some embodiments, adjacent chip sockets have different shapes.

A second aspect is directed to a panel comprising an array of chip sockets, each surrounded and defined by a polymer matrix framework comprising a grid of copper vias through the polymer matrix framework, wherein the panel comprises at least one region having sockets with a first set of dimensions for receiving one type of chip, and a second region having sockets with a second set of dimensions for receiving a second type of chip.

Optionally, at least one via is non cylindrical.

Optionally, at least one via is elongated.

In some embodiments, the frame comprises more than one via layer.

In some embodiments the elongated via is a coil.

Optionally, the at least one via is a coaxial via.

Optionally the frame further comprises glass fiber reinforcements within the polymer matrix.

Preferably, the frame further comprises a weave of glass fiber bundles within the polymer matrix.

In some embodiments, the frame comprises an array of two different sockets for two different dies in adjacent sockets.

Optionally, the different sockets have different shapes.

Optionally, the different sockets have different sizes.

A fourth aspect is directed to providing a method of fabricating an array of chip sockets surrounded by an organic matrix framework comprising: obtaining a sacrificial carrier; laying down a layer of photoresist and patterning with a grid of copper vias; plating copper into the grid; laminating with polymer dielectric; thinning and planarizing to expose ends of copper vias; removing the carrier, and machining chip sockets in the polymer dielectric.

Typically the carrier is a copper carrier that is removed by dissolving the copper.

Preferably the method comprises applying an etch-resistant layer over the carrier prior to depositing copper vias.

In one embodiment, the etch-resistant layer comprises nickel.

Optionally, the planarized polymer dielectric with exposed ends of copper vias is protected with an etch-resistant material whilst copper carrier is etched away.

Optionally, the etch-resistant material is a dry film photoresist.

In some embodiments, a copper seed layer is electroplated over the nickel.

In some embodiments, a copper seed layer is electroplated prior to depositing the nickel barrier layer.

In some embodiments, the grid is fabricated by punching out sockets leaving a framework.

In some embodiments, the grid is fabricated by machining out sockets using CNC, leaving a framework.

A variant method of fabricating an array of chip sockets surrounded by an organic matrix framework comprises:

• obtaining a sacrificial carrier;
• laying down a layer of photoresist and patterning with a grid of copper vias and a chip socket array;
• plating copper into the grid and the array;
• laminating with polymer dielectric;
• thinning and planarizing to expose ends of copper vias and the array;
• shielding the ends of the copper vias;
• dissolving the array, and
• removing the carrier.

In some embodiments, the via posts are elongated via posts and the chip sockets comprise a plurality of via posts separated by feature layers.

Optionally, the plurality of elongated via posts provides at least one continuous coil around at least one chip socket of the frame.

Preferably at least one socket is surrounded by an organic frame and a multilayer metal structure embedded in the organic frame and comprising a plurality of extended via post layers, such that each pair of adjacent via post layers are separated by a feature layer and the multilayer metal structure comprises a continuous coil.

BRIEF DESCRIPTION OF THE DRAWINGS

For a better understanding of the invention and to show how it may be carried into effect, reference will now be made, purely by way of example, to the accompanying drawings.

With specific reference now to the drawings in detail, it is stressed that the particulars shown are by way of example and for purposes of illustrative discussion of the preferred embodiments of the present invention only, and are presented in the cause of providing what is believed to be the most useful and readily understood description of the principles and conceptual aspects of the invention. In this regard, no attempt is made to show structural details of the invention in more detail than is necessary for a fundamental understanding of the invention; the description taken with the drawings making apparent to those skilled in the art how the several forms of the invention may be embodied in practice. In the accompanying drawings:

FIG. 1 is schematic illustration of a part of a polymer or composite grid having sockets therein for chips, and also having through vias around the sockets;

FIG. 2 is a schematic illustration of a panel used for fabricating embedded chips with surrounding through vias, showing how part of the panel, such as one pane may have sockets for a different type of chip;

FIG. 3 is schematic illustration of the part of the polymer or composite framework of FIG. 1, with chips within each socket, held in place by a polymer or composite material, such as a molding compound, form example;

FIG. 4 is a schematic illustration of a cross-section through part of the framework showing embedded chips held within each socket by a polymer material, and also showing through vias and pads on both sides of the panel;

FIG. 5 is a schematic illustration of a cross-section through a die containing an embedded chip;

FIG. 6 is a is a schematic illustration of a cross-section through a package containing a pair of dissimilar dies in adjacent sockets;

FIG. 7 is a schematic bottom view of a package such as that shown in FIG. 5;

FIG. 8 is a flowchart showing a manufacturing process for fabricating a polymer or composite panel including an array of through vias;

FIGS. 8(a) to 8(n) are schematic illustrations of the intermediate substructures obtained after each step of the flowchart 8;

FIG. 9 is a flowchart showing how drill-fill technology may be sued to create plated through holes, with sockets punched out;

FIGS. 9(a) to 9(e) are schematic illustrations of the intermediate substructures obtained after each step of flowchart 9, and

FIG. 10 is a schematic illustration of a frame with a three layer coil embedded therein consisting of elongated vias, showing the flexibility of the manufacturing technique and how it may be used to fabricate embedded transformers and the like.

DETAILED DESCRIPTION

In the description herein below, support structures consisting of metal vias in a dielectric matrix, particularly, copper via posts in a polymer matrix, such as polyimide, epoxy or BT (Bismaleimide / Triazine) or their blends, reinforced with glass fibers are considered.

It is a feature of Access' photo-resist and pattern or panel plating and laminating technology, as described in U.S. Pat. No. 7,682,972, U.S. Pat. No. 7,669,320 and U.S. Pat. No. 7,635,641 to Hurwitz et al., incorporated herein by reference, that large panels comprising very large arrays of substrates with very many via posts may be fabricated. Such panels are substantially flat and substantially smooth.

It is a further feature of Access' technology that vias fabricated by electroplating using photoresist, may be narrower than vias created by drill & fill. At present, the narrowest drill & fill vias are about 60 microns. By electroplating using photoresist, a resolution of under 50 microns, or even as little as 25 microns is achievable. Coupling ICs to such substrates is challenging. One approach for flip chip coupling is to provide copper pads that are flush with the surface of the dielectric. Such an approach is described in U.S. Ser. No. 13/912,652 to the present inventors.

All methods for attaching chips to interposers are costly. Wire bonding and flip chip technologies are costly and broken connections result in failure.

With reference to FIG. 1, there is shown part of an array 10 of chip sockets 12 defined by a framework 16 comprising a polymer matrix 14 and an array of metal vias 16 through the polymer matrix framework 14. .

The array 10 may be part of a panel comprising an array of chip sockets, each surrounded and defined by a polymer matrix framework comprising a grid of copper vias through the polymer matrix framework.

Each chip socket 12 is thus surrounded by a frame 18 of polymer with a number of copper through vias through the frame 18, arranged around the socket 12′.

The frame 18 may be a polymer applied as a polymer sheet, or may be a glass fiber reinforced polymer, applied as a pre-preg. More details may be found below with reference to FIGS. 8 and 9, where methods of manufacture are discussed.

With reference to FIG. 2, the applicant, Zhuhai Access' panels 20 are typically divided into a 2×2 array of blocks 21, 22, 23, 24 separated from each other by a main frame consisting of a horizontal bar 25 a vertical bar 26 and an external frame 27. The blocks comprise array of chip sockets 12 FIG. 1) Assuming a 5 mm×5 mm chip socket and Access' 21″×25″ panels, this manufacturing technique enables 10,000 chips to be packaged on each panel. In contradistinction, fabricating chip packages on a 12″ wafer, which is currently the largest wafer used in industry, enables only 2,500 chips to be processed in one go, so the economies of scale in fabricating on large panels will be appreciated.

Panels appropriate for this technology, may, however, vary in size somewhat. Typically, panels would be between about 12″×12″ and about 24″×30″. Some standard sizes in current use are 20″×16″, 20.3″×16.5″ and 24.7″×20.5″.

Not all the blocks of the panel 20 need to have chip sockets 12 of the size time. For example, in the schematic illustration of FIG. 2, the chip sockets 28 of the top right block 22 are larger than the chip sockets 29 of the other blocks 21, 23, 24. Furthermore, not only may one or more blocks 22 be used for a different sized socket for receiving a different sized chip, but any sub array of any size may be used to fabricate any specific die package, so despite the large throughputs, small runs of small numbers of die packages may be fabricated, enabling different die packages to be simultaneously processed for a specific customer, or different packages to be fabricated for different customers. Thus a panel 20 may comprise at least one region 22 having sockets 28 with a first set of dimensions for receiving one type of chip, and a second region 21 having sockets 29 with a second set of dimensions for receiving a second type of chip.

As described hereinabove with reference to FIG. 1, each chip socket 12 (28, 29 FIG. 2) is surrounded by a polymer frame 18 and in each block (21, 22, 23, 24—FIG. 2), an array of sockets 28 (29) are positioned.

With reference to FIG. 3, a chip 35 may be positioned in each socket 12, and the space around the chip 35 may be filled in with a polymer 36 which may or may not be the same polymer as that used for fabricating the frame 16. It may be a molding compound for example. In some embodiments, the matrix of the filler polymer 36 and that of the frame 16 may use similar polymers, but with different reinforcing fibers. For example, the frame may include reinforcing fibers, whereas the polymer 36 used for filling in the socket may be fiber free.

Typical die sizes may be anything from about 1.5 mm×1.5 mm, up to about 31×31 mm, with the sockets slightly larger to accommodate the intended dies with clearance. The thickness of the interposer frame must be at least the depth of the die, and is preferably 10 microns to 100 microns. Typically, the depth of the frame is the thickness of the die+a further 20 microns.

As a result of the embedding of chips 35 into the sockets 12, each individual chip is surrounded by a frame 38 having vias 14 therethrough, arranged around the edges of each die.

Using Access' via post technology, either by pattern plating or by panel plating followed by selective etching, the vias 14 may be fabricated as via posts and subsequently laminated with a dielectric material, using polymer films, or, for added stability, pre-pregs consisting of woven glass fiber bundles in a polymer matrix. In one embodiment, the dielectric material is Hitachi 705G. In another embodiment, MGC 832 NXA NSFLCA is used. In a third embodiment, Sumitomo GT-K may be used. In another embodiment, Sumitomo LAZ-4785 series films are used. In another embodiment, Sumitomo LAZ-6785 series is used. Alternative materials include Taiyo HBI and Zaristo-125.

Alternatively, the vias may be fabricated using what is generally known as drill-fill technology. First a polymer or fiber reinforced polymer matrix is fabricated and then, after curing, it is drilled with holes, either by mechanical or by laser drilling. The drilled holes may then be filled with copper by electroplating.

There are many advantages in fabricating the vias using via post rather than the drill-fill technology. In via post technology, since all vias may be fabricated simultaneously, whereas holes are drilled individually, the via post technology is faster. Furthermore, since drilled vias are cylindrical whereas via posts may have any shape. In practice all drill-fill vias have the same diameter (within tolerances), whereas via posts may have different shapes and sizes. Also, for enhanced stiffness, preferably the polymer matrix is fiber reinforced, typically with woven bundles of glass fibers. Where fiber in polymer pre-pregs are laid over upstanding via posts and cured, the posts are characterized by smooth, vertical sides. However, drill-fill vias typically taper somewhat and, where a composite is drilled, typically have rough surfaces which result in stray inductances that cause noise.

Generally, the vias 14 are in the range of 40 micron to 500 micron wide. If cylindrical, such as required for drill-fill and such as is often the case for via posts, each via may have a diameter in the range of 25 micron to 500 micron.

With further reference to FIG. 3, after fabricating the polymer matrix framework 16 with embedded vias, the sockets 12 may be fabricated by CNC or punching. Alternatively, using either panel plating or pattern plating, sacrificial copper blocks may be deposited. If the copper via posts 14 are selectively shielded, using a photoresist, for example, such copper blocks may be etched away to create the sockets 12.

A polymer framework of a socket array 38 with vias 14 in the frame 38 around each socket 12 may be used for creating individual and multiple chip packages, including multiple chip packages and built up multilayer chip packages, such as Package-on-Package “PoP” arrays.

Once the chips 35 are positioned in the sockets 12, they may be fixed in place using a polymer 36, such as a molding compound, a dry film or a pre-preg.

With reference to FIG. 4, copper routing layers 42, 43 may be fabricated on one or both sides of the framework 40 embedded with chips 35. Typically, the chips 35 are flip chips and are coupled to pads 43 that fat out beyond the edges of the chip 35. By virtue of the through vias 14, pads 42 on the upper surface allow coupling a further layer of chips for PoP packaging and the like. Essentially, it will be appreciated that the upper and lower pads 42, 43 enable building up further via posts and routing layers to create more complex structures.

A dicing tool 45 is shown. It will be appreciated that the array of packaged chips 35 in the panel 40 by be easily diced into individual chips 48 as shown in FIG. 5.

Referring to FIG. 6, in some embodiments, adjacent chip sockets may have different dimensions, including different sizes and / or different shapes. For example, a processor chip 35 may be positioned in one socket and coupled to a memory chip 55 positioned in an adjacent socket. Thus a package may include more than one chip, and may include different chips.

The pads 42, 43 may couple to chips via ball grid arrays BGA or land grid arrays LGA. At the current state of the art, via posts may be about 130 microns long. Where the chips 35, 55 are thicker than about 130 microns, it may be necessary to stack one via on top of another. The technology for stacking vias is known, and is discussed, inter alia, in co-pending applications U.S. Ser. No. 13/482,099 and U.S. Ser. No. 13/483,185 to Hurwitz et al.

With reference to FIG. 7, a die package 48 comprising a die 55 in a polymer frame 16 is shown from below, such that the die 55 is surrounded by the frame 16 and through vias 14 are provided through the frame 16 around the perimeter of the die 55. The die is positioned in a socket and held in place by a second polymer 36. The frame 16 is typically fabricated from a fiber reinforced pre-preg for stability. The second polymer 36 may also be a pre-preg but may be a polymer film or a molding compound. Typically, as shown the through vias 14 are simple cylindrical vias, but they may have different shapes and sizes. Some of the ball grid array of solder balls 57 on the chip 55 are connected to the through vias 14 by pads 43 in a fan out configuration. As shown, there may be additional solder balls that are coupled directly to a substrate beneath the chip. In some embodiments, for communication and data processing, at least one of the through vias is a coaxial via. In other embodiments, at least one via is a transmission line. Technologies for manufacturing coaxial vias are given in co-pending application U.S. Ser. No. 13/483,185, for example. Technologies for fabricating transmission lines are provided in U.S. Ser. No. 13/483,234 for example.

In addition to providing contacts for chip stacking, through vias 14 surrounding a chip may be used to isolate the chip from its surroundings and to provide Faraday shielding. Such shielding vias may be coupled to pads that interconnect the shielding vias over the chip and provide shielding thereto.

There may be more than one row of through vias surrounding the chip, and the inner row could be used for signaling and the outer row for shielding. The outer row could be coupled to a solid copper block fabricated over the chip that could thereby serve as a heat sink to dissipate heat generated by the chip. Different dies may be packaged in this manner.

The embedded chip technology with a frame having through vias described herein is particularly suited for analog processing, since the contacts are short, and there are a relatively small number of contacts per chip.

It will be appreciated that the technology is not limited to packaging IC chips. In some embodiments, the die comprises a component selected from the group consisting of fuses, capacitors, inductors and filters. Technologies for manufacturing inductors and filters are described in co-pending application number U.S. Ser. No. 13/962,316 to Hurwitz et al.

With reference to FIG. 8 and to FIGS. 8(a) to 8(l), a method of fabricating an array of chip sockets surrounded by an organic matrix framework comprises the steps of: obtaining a sacrificial carrier 80—8(a).

Optionally a seed layer of copper 82 is applied onto the copper barrier—8(b). An etch-resistant layer 84 is applied over the carrier—8(c), typically consisting of nickel and is typically deposited by a physical vapor process such as sputtering. It may alternatively be deposited by electroplating or electroless plating, for example. Other candidate materials include tantalum, tungsten, titanium, titanium-tungsten alloy, tin, lead, tin-lead alloy, all of which may be sputtered, and tin and lead may also be electroplated or electroless plated, the barrier metal layer is typically 0.1 to 1 micron thick. (Each candidate barrier layer material is later removed with appropriate solvent or plasma etching conditions.) After application of the barrier layer, a further copper seed layer 86 is applied—8(d). The copper seed layer is typically about 0.2 microns to 5 microns thick.

Steps 8(b) to 8(d) are preferable to ensure good adhesion of the barrier layer to the substrate, good adhesion and growth of vias, and to enable subsequent removal of the substrate by etching without damaging vias. Although best results include these steps, they are, however, optional, and one or more may not be used.

A layer of photoresist 88 is now applied—step (e), FIG. 8(e) and patterned with a pattern of copper vias—8(f). Then copper 90 is plated into the pattern—8(g), and the photoresist 88 is stripped away—8(h). The upstanding copper vias 90 are laminated with polymer dielectric 92—8(i) which may be a fiber reinforced polymer matrix pre-preg. The laminated via array is thinned and planarized to expose the ends of the copper vias—8(j). The carrier is then removed.

Optionally and preferably, the planarized polymer dielectric with exposed ends of copper vias is protected by applying an etch-resistant material 94—8(k) such as a photoresist or dielectric film, prior to the copper carrier 80 being etched away 8(l). Typically the carrier is a copper carrier 80 that is removed by dissolving the copper. Ammonium -hydroxide or copper chloride may be used to dissolve the copper.

The barrier layers may then be etched away—8(m), and the etch protectant layer 94 may be removed—step 8(n).

Although not described herein, it will be appreciated that the upstanding copper vias could be fabricated by panel plating and selectively etching away superfluous copper to leave the vias. Indeed, the sockets could alternatively be fabricated by selectively etching away parts of a copper panel whilst shielding the vias.

Although via post technology is preferred, drill & fill technology can also be used. With reference to FIG. 9, in another variant method, a carrier consisting of a copper clad laminate (CCL) 100 is obtained—9(a). CCLs have thicknesses of 10s to hundreds of microns. A typical thickness if 150 microns. Holes 102 are drilled through the CCL—9(b). The holes 102 may have a diameter of 10s to hundreds of microns. Typically, the diameter of the holes is 150 microns.

The through holes are now plated to create plated through holes 104—9(c).

The copper clad laminate 100 is then ground or etched to remove the surface copper layers 106, 108, leaving the laminate 110 with plated through hole (Pth) copper vias 104—9(d).

Then, using CNC or a punch, sockets 112 are fabricated through the laminate for receiving chips—9(e).

As described hereinabove, using the preferred via post technology, electroplated vias deposited into photoresist may have any shape or size. Furthermore, a frame can include 2 or more via layers separated by pads. With reference to FIG. 10, this flexibility enables embedding a coil of copper 200, typically comprising via posts, to be embedded within a dielectric frame 202 around a cavity 204. By way of example only, the coil 200 shown has three layers of extending via posts 206, 207, 208, possibly via posts deposited on feature layers. The layers 206, 207, 208 are coupled together by vertical elements 209, 210. The vertical elements 209, 210 may be via posts or feature layers, or a via post on a feature layer. Coil 200 could provide Faraday shielding to an embedded chip, for example. If an iron core is deposited within a socket 204 having a frame 202 that includes a coil 200, a transformer may be fabricated. Thus the polymer frames with copper vias of the present invention enable fabrication of a whole range of frames with copper vias therein for embedding a range of components.

In practice, the coil of copper via post 200 will generally comprise elongated via posts coupled together by feature layers, or elongated feature layers coupled by via posts. In general, via post layers alternate with feature layers and a coil has to be built up layer by layer.

Persons skilled in the art will appreciate that the present invention is not limited to what has been particularly shown and described hereinabove. Rather the scope of the present invention is defined by the appended claims and includes both combinations and sub combinations of the various features described hereinabove as well as variations and modifications thereof, which would occur to persons skilled in the art upon reading the foregoing description.

In the claims, the word “comprise”, and variations thereof such as “comprises”, “comprising” and the like indicate that the components listed are included, but not generally to the exclusion of other components.

Claims

1. An array of chip sockets defined by an organic matrix framework surrounding sockets through the organic matrix framework and further comprising a grid of metal vias through the organic matrix framework.

2. The array of chip sockets of claim 1, wherein each chip socket is surrounded with a frame of organic matrix including copper vias through the frame.

3. The array of chip sockets of claim 1, wherein the organic matrix framework further comprises glass fiber bundles.

4. The array of chip sockets of claim 1, wherein the copper vias are via posts.

5. The array of chip sockets of claim 1, wherein each via is in the range of 25 micron to 500 micron wide.

6. The array of chip sockets of claim 1, wherein each via is cylindrical and has a diameter in the range of 25 micron to 500 micron.

7. The array of chip sockets of claim 7 wherein a frame around at least one socket comprises alternating via posts and feature layers and comprises at least one via post layer and one feature layer.

8. The array of chip sockets of claim 1 wherein the grid of metal vias through the organic matrix framework comprises a plurality of via layers.

9. The array of chip sockets of claim 7 wherein a frame around at least one socket comprises a continuous coil of alternating via posts and feature layers spanning at least one via post layer and one feature layer.

10. The array of claim 7 wherein the via posts comprise elongated vias posts.

11. The array of chip sockets of claim 9 wherein the continuous coil of elongated vias posts spans a plurality of via post layers.

12. The array of chip sockets of claim 1, comprising adjacent chip sockets of different dimensions.

13. The array of chip sockets of claim 12, comprising adjacent chip sockets of different size.

14. The array of chip sockets of claim 12, comprising adjacent chip sockets of different shape.

15. A panel comprising an array of chip sockets, each surrounded and defined by an organic matrix framework comprising a grid of copper vias through the organic matrix framework, wherein said panel comprises at least one region having sockets with a first set of dimensions for receiving one type of chip, and a second region having sockets with a second set of dimensions for receiving a second type of chip.

16. A method of fabricating an array of chip sockets surrounded by an organic matrix framework comprising:

obtaining a sacrificial carrier;

laying down a layer of photoresist and patterning with a grid of copper via posts;

plating copper into the grid;

laminating with polymer dielectric;

thinning and planarizing to expose ends of copper vias;

removing the carrier, and machining chip sockets in the polymer dielectric.

17. The method of claim 16, wherein the carrier is a copper carrier that is removed by dissolving the copper.

18. The method of claim 16 further comprising applying an etch resistant layer over the carrier prior to depositing the copper via posts.

19. The method of claim 16, wherein the etch resistant layer comprises nickel.

20. The method of claim 16, wherein the planarized polymer dielectric with exposed ends of copper vias posts is protected with an etch resistant material whilst copper carrier is etched away.

21. The method of claim 20 wherein the etch resistant material is a photoresist.

22. The method of claim 18 wherein a copper seed layer is electroplated over the nickel.

23. The method of claim 18 wherein a copper seed layer is electroplated prior to depositing the nickel barrier layer.

24. The method of claim 16, wherein the grid is machined by one of punching out sockets leaving a framework or by CNC.

25. A method of fabricating an array of chip sockets surrounded by an organic matrix framework comprising:

obtaining a sacrificial carrier;

laying down a layer of photoresist and patterning with a grid of copper via posts and a chip socket array;

plating copper into the grid and the array;

laminating with polymer dielectric;

thinning and planarizing to expose ends of copper vias and the array;

shielding the ends of the copper vias posts;

dissolving the array, and removing the carrier.

26. The method of claim 25 wherein the via posts are elongated via posts and at least one chip socket is surrounded by an organic matrix frame with an embedded metallic structure comprise at least one elongated via post and at least one feature layer.

27. The method of claim 25 wherein the elongated via post and feature layer comprises a continuous coil.

28. The method of claim 25 wherein at least one socket is surrounded by an organic frame and a multilayer metal structure embedded in the organic frame and comprising a plurality of extended via post layers, such that each pair of adjacent via post layers are separated by a feature layer and the multilayer metal structure comprises a continuous coil.