This document relates to integrated circuits, and more particularly to assemblies having dies that include semiconductor integrated circuits.
In fabrication of integrated circuits, one or more circuits are manufactured in a semiconductor wafer and are then separated into “dies” (also called “chips”) in a process called “singulation” or “dicing”. The dies, such as shown at 110 in
Encapsulant 150 (e.g. epoxy with silica or other particles) protects the dies 110 and the connections 140 from moisture and other contaminants, ultraviolet light, alpha particles, and possibly other harmful elements. The encapsulant also strengthens the die-to-WS attachment against mechanical stresses, and the encapsulant helps conduct heat away from the dies (to an optional heat sink 160 or directly to the ambient (e.g. air)). However, the encapsulant can cause warpage if the encapsulant's thermal expansion coefficient (CTE) does not match the CTE of the dies or the WS.
The wiring substrate can be an interposer, i.e. an intermediate substrate used to accommodate a mismatch between die fabrication technology and printed wiring substrates (PWS). More particularly, the die's contact pads 110C can be placed much closer to each other (at a smaller pitch) than PWS pads 120C. Therefore (
The interposer substrate 120.1S should be as thin as possible to shorten the signal paths between dies 110 and PWS 120.2 and thus make the system faster and less power hungry. Also, if the interposer is thin, fabrication of metallized vias 224 is facilitated. However, thin interposers are hard to handle: they are brittle, easily warped, and do not absorb or dissipate heat during fabrication. Therefore, a typical fabrication process attaches the interposer to a temporary substrate (“support wafer”) during fabrication. The support wafer is later removed. Attaching and detaching temporary support wafers is burdensome, and should be avoided if possible. See U.S. Pat. No. 6,958,285 issued Oct. 25, 2005 to Siniaguine.
It is desirable to provide improved protection of dies from mechanical stresses, heat, and harmful elements, and improved accommodations for thin interposers.
This section summarizes some of the exemplary implementations of the invention.
In some embodiments, the dies are protected by a reinforcement frame which is a separate substrate attached to a wiring substrate. The dies are located in openings in the reinforcement frame. Each opening may be a cavity, a through-hole, or both (i.e. a cavity with one or more through-holes). In some cavity embodiments, the reinforcement frame is similar to cap wafers used to protect MEMS components (Micro-Electro-Mechanical Structures); see K. Zoschke et al., “Hermetic Wafer Level Packaging of MEMS Components Using Through Silicon Via and Wafer to Wafer Bonding Technologies” (2013 Electronic Components & Technology Conference, IEEE, pages 1500-1507); see also U.S. Pat. No. 6,958,285 issued Oct. 25, 2005 to Siniaguine. However, in some embodiments, the reinforcement frame improves heat dissipation from the dies, and may reduce or eliminate the need for encapsulant. In some embodiments (e.g. those with through-holes), reinforcement frames allow much flexibility for fabrication sequences and intermediate testing during manufacturing. A reinforcement frame may or may not have its own circuitry connected to the dies or to the wiring substrate.
In some embodiments, an opening contains multiple dies.
The invention is not limited to the features and advantages described above, and includes other features described below.
The embodiments described in this section illustrate but do not limit the invention. In particular, the invention is not limited to particular materials, processes, dimensions, or other particulars except as defined by the appended claims.
Substrate 120.1S is patterned to form blind vias 224B (
The vias are then metallized. If substrate 120.1S is silicon, this can be done as follows. Photoresist 320 and protective layer 310 are removed, and a dielectric layer 324 (
Then metal 224M (
For ease of description, we will refer to vias 224 as “metallized”, but non-metal conductive materials can also be used (e.g. doped polysilicon).
If layer 224M does not fill the vias but is only a liner on the via surfaces, some other material (not shown) can be formed on layer 224M as a filler to fill the vias and provide a planar top surface for the wafer. This filler material can be polyimide deposited by spin coating for example.
Optionally, RDL 210.T (
Interposer 120.1 may include transistors, resistors, capacitors, and other devices (not shown) in substrate 120.1S and redistribution layer 210.T. These devices can be formed before, during and/or after the fabrication of vias 224 and RDL 210.T using the process steps described above and/or additional process steps. Such fabrication techniques are well known. See e.g. the aforementioned U.S. Pat. No. 6,958,285 and pre-grant patent publication 2012/0228778, both incorporated herein by reference.
Dies 110 are attached to contact pads 120.1C.T by connections 140.1, using possibly prior art methods described above in relation to
Optionally, an encapsulant (not shown) can be formed under the dies (as underfill) and/or around the dies (to completely or partially cover the dies' sidewalls), and perhaps above the dies (to completely cover the dies' top and sidewall surfaces), possibly by prior art techniques (e.g. including molding and/or capillary action for underfill). The encapsulant can be any suitable material (e.g. epoxy with silica or other particles). No encapsulant is used in some embodiments. Other embodiments use an encapsulant, but the requirements for the encapsulant are relaxed because the dies will be protected by a reinforcement frame in the form of an additional, protective substrate 410 (
Another possible factor is high thermal conductivity to enable the substrate 410 to act as a heat sink. For example, metal may be appropriate.
Openings 414 (
Then photoresist 430 is removed (
As shown in
In
In other embodiments, the dies are not bonded to the cavities' top surfaces, and thus the dies' top surfaces can slide laterally along the cavities' top surfaces in thermal movement. This may reduce the thermal stresses, e.g. if the die-interposer CTE matching is better than the matching between the interposer and protective substrate 410.
As noted above, in some embodiments the dies are underfilled and/or encapsulated from above by a suitable protective material (not shown in
To ensure physical contact between the dies (or the encapsulant) and the cavities, the top surfaces of the dies (or encapsulant) should have uniform height. To improve the height uniformity, the dies (or encapsulant) can be polished before joining of substrate 410 to interposer 120.1. Suitable polishing processes include lapping, grinding, and chemical mechanical polishing (CMP). Also, before inserting the dies into cavities, the cavity surfaces and/or the dies can be provided with a suitable temperature interface material (TIM, not shown here but shown at 525 in
After the bonding of substrate 410 to interposer 120.1, the interposer is thinned from the bottom to expose the metal 224M (
Advantageously, interposer 120.1 is kept flat by substrate 410, so the handling of the assembly 504 is facilitated. Substrate 410 also improves mechanical integrity (e.g. increases rigidity and weight) to further facilitate handling of the assembly. Also, substrate 410 helps absorb and dissipate the heat generated during this and subsequent fabrication stages and in subsequent operation of assembly 504. The final thickness of substrate 120.1S can therefore be very low, e.g. 50 microns or even 5 microns or less. Hence, blind vias 224B (
If desired, protective substrate 410 can be thinned from the top (this is not shown in
Subsequent process steps depend on the particular application. In some embodiments (
As noted above, protective substrate 410 and interposer 120.1 can be bonded by adhesive, and
In some embodiments, adhesive 610 is a punched adhesive tape.
Referring to
Referring to
Subsequent processing of the structures of
The process step sequences described above are not limiting; for example, the vias 224 can be formed after the interposer thinning
Interposer 120.1 with the dies attached is then bonded to protective substrate 410 (
Then metallized vias 224 are formed from the interposer bottom. An exemplary process is as follows:
1. Dielectric 920 (e.g. silicon dioxide or silicon nitride) is deposited (e.g. by sputtering or CVD) to cover the bottom surface of interposer substrate 120.1S.
2. Vias (through-holes) are formed (by a masked etching or laser drilling or some other process) from the bottom through dielectric 920 and substrate 120.1S. The vias terminate at contact pads 910.
3. Dielectric 930 (e.g. silicon dioxide or silicon nitride) is deposited (e.g. by sputtering or CVD) to cover the bottom surface of interposer substrate 120.1S and to line the vias. Dielectric 930 covers the contact pads 910 from the bottom.
4. Dielectric 930 is etched to expose the contact pads 910. This can be a masked etch. Alternatively, a blanket anisotropic (vertical) etch can be used to remove the dielectric 930 from over at least a portion of each contact pad 910 while leaving the dielectric on the via sidewalls. The vertical etch may or may not remove dielectric 930 outside the vias.
5. A conductive material 224M (e.g. metal) is formed in the vias, possibly by the same techniques as described above (e.g. copper electroplating). The conductive material is not present outside the vias (e.g. it can be polished away by CMP). The conductive material may fill the vias or just line the via surfaces. The conductive material in each via physically contacts the corresponding pad 910.
Subsequent processing steps can be as described above in connection with
Vias 224 are optional, and further the substrate 120.1 can be any wiring substrate, such as shown at 120 in
In some embodiments, vias 224 are formed partly before and partly after the interposer thinning. For example, in some embodiments, the interposer is processed to the stage of
The techniques described above in connection with
The dies can be stacked one above another in the same cavity (see
In some embodiments, substrate 410S has circuitry, possibly connected to the circuitry in the dies and/or the interposer 120.1S or the PWS. See
The invention is not limited to the embodiments described above or below. For example, the vias 224 can be formed after the RDLs, and can be etched through one or both of the RDLs. Different features described above or below can be combined. For example, in
A cavity 414 may include dies, stacks, or other packages of different heights (e.g. as in
At step 1420, the maximum Tmin value is determined (this value is denoted by M in
At step 1430, the M value is used to determine the cavity depth Cd. For example, Cd may be set to the M value plus a value determined based on the available manufacturing tolerances (i.e. possible manufacturing errors) and/or desired heat dissipation capabilities and/or the bonding technology (e.g. the thickness of layer 610 or 810 or 820), and/or possibly other parameters.
At step 1440, for each module whose Tmin is less than the maximum value (M), the module's thickness is increased as desired. In the example of
Steps 1420, 1430, 1440 are performed automatically in some embodiments, for example by a computer comprising computer processor(s) executing software instructions stored in a computer storage (e.g. memory) or by some other circuitry.
Further, as shown in
In some embodiments, a cavity with varying depths is provided even for modules of the same height.
Also (
As noted above, multiple protective substrates 410 can be attached to the same interposer. An example is shown in
This type of structure can provide multiple advantages. In particular, the interposer areas between the frames 410 are accessible and can be used for test pads 1610: the test pads can be connected to other contact pads in RDL 210.T and/or to metallized vias 224M. The test pads facilitate testing of the assembly before and/or after dicing (dicing is omitted in some embodiments). In some embodiments, test pads are located on dicing lines, i.e. a test pad can be cut through during dicing, and can thus be destroyed or can merely be divided into multiple test pads which can be used for testing each die after dicing.
Also, thermal stresses that may be present before dicing are lower than for a wafer-size (continuous) reinforcement frame.
Further, since each frame 410 covers less than all the dies 110, each frame 410 is easier to align when it is placed on the interposer (because each frame has to be aligned with just the modules covered by the frame). Also, the interposer may have alignment marks (not shown) in the top surface between the positions of frames 410, to facilitate the alignment of each frame.
For alignment purposes, a reinforcement frame 410 may have protrusions or slots that mate with the slots or protrusions on the interposer. See
As noted above, openings 410 can be cavities as shown above, or can be through-holes, or can be cavities with through-holes.
Similar to
While a through-hole-type frame 410 (such as in
The through-hole scheme increases manufacturing flexibility in that the dies 110 and frames 410 can be attached to interposer 120.1 in any order. An exemplary manufacturing sequence is illustrated in the flowchart of
Dicing is performed at step 2380. If needed (step 2384), each die (i.e. each stack) 504S obtained at step 2380 is attached to another substrate, e.g. PWS 120.2 (this is shown in
Many variations are possible.
Some aspects of some embodiments are described by the following clauses:
Clause 1 describes a manufacture comprising:
a first substrate (e.g. interposer 120 or 120.1, or interposer substrate 120.1S) comprising one or more first contact pads (e.g. top contact pads 120.1C.T);
a plurality of modules (e.g. dies 110 or other assemblies/packages, e.g. modules 1310) attached to the first substrate, at least one module comprising a semiconductor integrated circuit, the module comprising one or more contact pads each of which is attached to a respective first contact pad (of note, there could also be dummy modules, e.g. dummy dies, if the assembly was initially designed to accommodate more modules than needed for a particular embodiment);
a reinforcement frame (e.g. 410 or 410S) comprising one or more cavities, the reinforcement frame being attached to the first substrate, wherein at least part of each module is located in a corresponding cavity in the reinforcement frame (see e.g.
Of note, the term “cavity” as used herein covers a cavity with a through-hole. However, the term “cavity” as used herein has a depth which is a parameter that limits the height of modules that can be placed in the cavity. Thus, if an opening 414 has vertical walls and no “roof” (as in
Clause 2 describes a manufacture comprising:
a first substrate (e.g. interposer 120 or 120.1, or interposer substrate 120.1S) comprising one or more first contact pads;
a plurality of modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad;
a reinforcement frame comprising one or more cavities, the reinforcement frame being attached to the first substrate, wherein at least part of each module is located in a corresponding cavity in the reinforcement frame (of note, multiple modules may be located in the same cavity);
wherein the plurality of modules comprises a first module and a second module that are at least partially located in the same cavity which is deeper over the first module than over the second module (as in
Clause 3 describes a manufacture comprising:
a first substrate comprising one or more first contact pads;
a plurality of modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad;
a reinforcement frame comprising a plurality of cavities, the reinforcement frame being attached to the first substrate, wherein at least part of each module is located in a corresponding cavity in the reinforcement frame;
wherein the plurality of modules comprises a first module and a second module taller than the first module, and the cavity corresponding to the second module is deeper than the cavity corresponding to the first module (as in
Clause 4 describes a method (e.g. as in
(a) determining a minimum thickness Tmin for each module;
(b) determining a maximum value M of the minimum thicknesses of the modules;
(c) determining a depth of the first cavity by a process using the maximum value M;
(d) if any module's minimum thickness Tmin is less than M, then determining, for at least one module whose minimum thickness Tmin is less than M, if the module's thickness is to be increased, and if the module's thickness is to be increased than increasing the module's thickness.
Clause 5 describes the method of clause 4 further comprising manufacturing the modules based on the modules' thicknesses.
Clause 6 describes the method of clause 4 or 5 wherein at least one module's thickness is increased in operation (d), and increasing the module's thickness comprises increasing a thickness of at least one semiconductor integrated circuit in the module.
Clause 7 describes a manufacture comprising:
a first substrate comprising a first side and one or more first contact pads at the first side;
one or more modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad; and
a plurality of reinforcement frames attached to the first substrate (as in
In some embodiments, at least one opening is a cylindrical through-hole. “Cylindrical” is not limited to “circular”; for example, in
Clause 8 describes the manufacture of clause 7 wherein the reinforcement frames are spaced from each other.
Clause 9 describes the manufacture of clause 7 or 8 wherein the first substrate comprises one or more test pads (e.g. 1610) for testing the manufacture which are located outside of the reinforcement frames.
Clause 10 describes the manufacture of clause 9 wherein at least one test pad is located between at least two reinforcement frames.
Clause 11 describes a method for manufacturing a manufacture, the method comprising:
obtaining a first substrate comprising a first side and one or more first contact pads at the first side;
obtaining one or more modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad; and
attaching a plurality of reinforcement frames to the first substrate, each reinforcement frame comprising one or more openings, at least part of each module being located in a corresponding opening in a corresponding reinforcement frame. See
Clause 12 describes the method of clause 11 wherein the reinforcement frames are spaced from each other.
Clause 13 describes the method of clause 11 or 12 further comprising dicing the first substrate between at least two reinforcement frames to form a plurality of dies, each reinforcement frame being in one of the dies.
Clause 14 describes the method of clause 11, 12 or 13 wherein the first substrate comprises one or more test pads for testing the manufacture which are located outside of the reinforcement frames.
Clause 15 describes the method of clause 14 wherein at least one test pad is located between at least two reinforcement frames.
Clause 16 describes a manufacture comprising:
a first substrate comprising a first side and one or more first contact pads at the first side;
one or more modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad; and
one or more reinforcement frames attached to the first substrate, each reinforcement frame comprising one or more openings, at least part of each module being located in a corresponding opening in a corresponding reinforcement frame;
wherein the first substrate comprises a portion laterally surrounding the one or more reinforcement frames. For example, in
Clause 17 describes the manufacture of clause 16 wherein the portion laterally surrounding the one or more reinforcement frames comprises one or more test pads for testing the manufacture.
Clause 18 describes the manufacture of clause 17 wherein at least one test pad is electrically connected to at least one module (e.g. by interconnect lines in RDL 210.T in
Clause 19 describes a manufacture comprising:
a first substrate comprising a first side and one or more first contact pads at the first side;
one or more modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad; and
one or more reinforcement frames attached to the first substrate, each reinforcement frame comprising one or more openings, at least part of each module being located in a corresponding opening in a corresponding reinforcement frame;
wherein in at least one reinforcement frame, at least one opening comprises a through-hole. See
Clause 20 describes the manufacture of clause 19 wherein the manufacture comprises one or more test pads for testing the manufacture which are accessible through the through-hole and are laterally surrounded by the at least one reinforcement frame. See e.g. test pads 1610 in
Clause 21 describes the manufacture of clause 20 wherein at least one test pad is part of the first substrate (e.g. as the test pad 1610 which is part of RDL 210.T in FIG. 20.1).
Clause 22 describes the manufacture of clause 20 or 21 wherein at least one test pad is part of a module at least partially located in the at least one opening (e.g. the test pad on top of die 110 in
Clause 23 describes a method for making a manufacture (e.g. as in
obtaining a first substrate comprising a first side and one or more first contact pads at the first side;
obtaining one or more modules attached to the first substrate, each module comprising a semiconductor integrated circuit, each module comprising one or more contact pads each of which is attached to a respective first contact pad; and
attaching one or more reinforcement frames to the first substrate, each reinforcement frame comprising one or more openings, at least part of each module being located in a corresponding opening in a corresponding reinforcement frame;
wherein in at least one reinforcement frame, at least one opening comprises a through-hole.
Clause 24 describes the method of clause 23 wherein the at least one reinforcement frame is attached to the first substrate before at least part of at least one module partially located in the through-hole.
Clause 25 describes the manufacture of clause 19 further comprising one or more heat sinks (e.g. 160) each of which overlies one or more through-holes in one or more reinforcement frames, wherein at least one heat sink overlying at least one through-hole in at least one reinforcement frame is attached to the reinforcement frame and/or to at least one module at least partially located in the through-hole, each heat sink having a higher thermal conductivity than each reinforcement frame.
Clause 26 describes the manufacture of claim 25 wherein at least one heat sink overlying at least one through-hole in at least one reinforcement frame is attached to the reinforcement frame.
Clause 27 describes the manufacture of claim 25 wherein at least one heat sink overlying at least one through-hole is attached to at least one module at least partially located in the through-hole.
Clause 28 describes the manufacture of claim 19 wherein the first substrate comprises a first alignment feature, and at least one reinforcement frame comprises a second alignment feature, and one of the first and second alignment features is a recess, and the other one of the first and second alignment features a protrusion having no electrical functionality and at least partially located in the recess.
The invention is not limited to the examples above. Other embodiments and variations are within the scope of the invention, as defined by the appended claims.
The present application is a continuation-in-part of U.S. patent application Ser. No. 14/214,365, filed 14 Mar. 2014 by Shen et al., titled “INTEGRATED CIRCUITS PROTECTED BY SUBSTRATES WITH CAVITIES, AND METHODS OF MANUFACTURE”, incorporated herein by reference, which claims priority of U.S. provisional application No. 61/952,066 filed on Mar. 12, 2014, titled “INTEGRATED CIRCUITS PROTECTED BY SUBSTRATES WITH CAVITIES, AND METHODS OF MANUFACTURE”, incorporated herein by reference. The present application also claims priority of the aforementioned provisional application No. 61/952,066.
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Number | Date | Country | |
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20150262972 A1 | Sep 2015 | US |
Number | Date | Country | |
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61952066 | Mar 2014 | US |
Number | Date | Country | |
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Parent | 14214365 | Mar 2014 | US |
Child | 14288064 | US |