 |
Claims  |
|
|
We claim:
1. A vertical integrated circuit (IC) chip stack, comprising:
a plurality of vertically stacked chip carriers, each carrier comprising:
a dielectric body having a floor and side walls bounding a cavity,
an IC chip lodged in said cavity wherein the upper surface of said chip,
except for the uppermost chip in the stack, is in direct and thermal
contact with the floor of the carrier immediately above it in the stack,
electrical routing extending through the carrier body, and
electrical connectors connecting said IC chip to its carrier's routing,
electrical intercarrier interconnects between the routings for adjacent
carriers, and
stack contacts connected to respective intercarrier interconnects for
making external connections to the stack.
2. The IC chip stack of claim 1, the electrical routing for at least some
of said carriers comprising electrical intracarrier interconnects carried
by the floors of said carriers and interconnecting different circuit
portions of their respective chips.
3. The IC chip stack of claim 2, wherein the intracarrier interconnects for
at least some of said carriers are arranged in multiple layers within
their carrier floors.
4. The IC chip stack of claim 1, wherein said intercarrier interconnects
extend through the side walls of their respective carriers.
5. The IC chip stack of claim 4, wherein said intercarrier interconnects
include electrically conductive contacts between adjacent carriers that
mechanically secure the carriers to each other within said stack.
6. The IC chips stack of claim 1, wherein an array of chip carriers is
provided on at least one carrier level of said stack, with the chip
carriers in each such horizontal level electrically interconnected with at
least one other chip carrier in the same level by interconnecting their
respective electrical routings.
7. The IC chip stack of claim 1, further comprising a wiring board, with
said chip stack mounted to said wiring board and said stack contacts
electrically connected to corresponding contacts on said wiring board.
8. The IC chip stack of claim 7, wherein said stack contacts comprise
electrically conductive contacts between respective intercarrier
interconnects and wiring board contacts that mechanically secure the stack
to the wiring board.
9. The IC chip stack of claim 7, said stack contacts comprising wire bond
pads, wherein said wire bond pads are wire bonded to said wire board
contacts.
10. The IC chip stack of claim 1, wherein said chips are flip-chip mounted
to the routings of their respective cavities.
11. The IC chip stack of claim 1, wherein said chips are wire bonded to the
routings of their respective carriers, further comprising dielectric
spacers extending from the upper surface of each chip, except for the
uppermost chip in the stack, to the floor of the carrier immediately above
it in the stack, said spacers leaving peripheral clearances on the upper
surfaces of their respective chips, and wire bond pads within said
peripheral clearances.
12. The IC chip stack of claim 11, where said carriers include shelves
adjacent the upper surfaces of their respective chips, with wire bond pads
provided on said shelves and connected to the routings for their
respective carriers, and wire bonds extending between corresponding wire
bond pads on said chips and on their carrier shelves.
13. The IC chip stack of claim 1, further comprising at least one discrete
circuit element disposed in the floor of at least one of said carriers and
connected to the chip in said carrier by the carrier's routing.
14. The IC chip stack of claim 1, further comprising vias filled with a
thermally conductive material extending through the floor of the lowermost
carrier in said stack to transport heat away from the chip in said
lowermost carrier.
15. The IC chip stack of claim 14, wherein said vias each comprise a
plurality of staggered via segments to inhibit air flow through the floor
of said lowermost carrier.
16. The IC chip stack of claim 1, wherein the upper surface but not the
lower surface of the lowermost chip in the stack bears electrical
circuitry, the floor of the lowermost carrier in the stack comprises a
metal heat sink, and said lowermost chip is in thermal contact with said
heat sink.
17. The IC chip stack of claim 1, wherein the side walls of the uppermost
carrier in said stack extend at least to the level of the upper surface of
the chip in said uppermost carrier, and further comprising a lid
hermetically sealing said uppermost carrier.
18. A vertical integrated circuit (IC) chip stack, comprising:
a plurality of vertically stacked chip carriers, each carrier comprising:
a plurality of joined dielectric tape layers, of which a plurality of lower
tape layers provide a floor for the carrier and at least one upper tape
layer has an opening which is bounded on the bottom by said floor, said
opening forming a cavity in the carrier,
an IC chip lodged in said cavity wherein the upper surface of each chip,
except for the uppermost chip in the stack, is in direct and thermal
contact with the floor of the carrier immediately above it in the stack,
horizontal electrical routing extending along at least one tape layer in
said floor,
vertical electrical routing extending through at least the uppermost tape
layer in said floor to said horizontal electrical routing, and
electrical connectors connecting said IC chip to said vertical electrical
routing,
electrical intercarrier interconnects between the vertical electrical
routings for adjacent carriers, and
stack contacts connected to respective intercarrier interconnects for
making external connections to the stack.
19. The IC chip stack of claim 18, wherein said intercarrier interconnects
extend through the walls of their respective carriers.
20. The IC chip stack of claim 19, wherein said intercarrier interconnects
include electrically conductive contacts between adjacent carriers that
mechanically secure the carriers to each other within said stack.
21. The IC chips stack of claim 18, wherein an array of chip carriers is
provided on at least one carrier level of said stack, with the chip
carriers in each such horizontal level electrically interconnected with at
least one other chip carrier in the same level by interconnecting their
respective electrical routings.
22. The IC chip stack of claim 18, further comprising a wiring board, with
said chip stack mounted to said wiring board and said stack contacts
electrically connected to corresponding contacts on said wiring board.
23. The IC chip stack of claim 22, wherein said stack contacts comprise
electrically conductive contacts between respective intercarrier
interconnects and wiring board contacts that mechanically secure the stack
to the wiring board.
24. The IC chip stack of claim 22, said stack contacts comprising wire bond
pads, wherein said wire bond pads are wire bonded to said wire board
contacts.
25. The IC chip stack of claim 18, wherein said chips are flip-chip mounted
to the routings of their respective cavities.
26. The IC chip stack of claim 18, wherein said chips are wire bonded to
the routings of their respective carriers, further comprising dielectric
spacers extending from the upper surface of each chip, except for the
uppermost chip in the stack, to the floor of the carrier immediately above
it in the stack, said spacers leaving peripheral clearances on the upper
surfaces of their respective chips, and wire bond pads within said
peripheral clearances.
27. The IC chip stack of claim 26, where said carriers include shelves
adjacent the upper surfaces of their respective chips, with wire bond pads
provided on said shelves and connected to the routings for their
respective carriers, and wire bonds extending between corresponding wire
bond pads on said chips and on their carrier shelves.
28. The IC chips stack of claim 18, further comprising at least one
discrete circuit element disposed along the surface of at least one of the
dielectric tape layers in the floor of at least one of said carriers and
connected to the chip in said carrier by the carrier's routing.
29. The IC chip stack of claim 18, further comprising vias filled with a
thermally conductive material extending through the floor of the lowermost
carrier in said stack to transport heat away from the chip in said
lowermost carrier.
30. The IC chip stack of claim 29, wherein said vias each comprise a
plurality of via segments that are staggered between successive tape
layers to inhibit air flow through the floor of said lowermost carrier.
31. The IC chip stack of claim 18, wherein the upper surface but not the
lower surface of the lowermost chip in the stack bears electrical
circuitry, the floor of the lowermost carrier in the stack comprises a
metal heat sink, and said lowermost chip is in thermal contact with said
heat sink.
32. The IC chip stack of claim 18, wherein said upper tape layers for the
uppermost carrier in said stack extend at least to the level of the upper
surface of its chip, and further comprising a lid for hermetically sealing
said uppermost carrier.
33. The IC chip stack of claim 18, wherein said joined dielectric tape
layers comprise fused low temperature cofired ceramic (LTCC) tape layers. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to multi-chip module (MCM) circuit packages
fabricated with dielectric tapes such as low temperature cofired ceramic
(LTCC) tape, and more specifically to such circuit structures that are
assembled in a three-dimensional stack.
2. Description of the Related Art
MCM packages generally include a dielectric structure consisting of a
number of layers of insulating material with electrical circuit elements
such as resistors, inductors and capacitor plates formed on their
surfaces, and conductive routing patterns interconnecting the various
elements. The insulating layers are thermally fused together so that the
circuit elements are buried, with vertical interconnects (vias) extending
through the insulating layers to interconnect circuit elements on adjacent
layers.
One or more IC chips and/or discrete components are mounted to the surface
of the dielectric structure and connected to its routing by wire bond,
flip-chip or other connection techniques. In a flip-chip configuration, a
surface of an IC chip upon which bonding pads are formed faces the
dielectric structure, and the bonding pads are connected to mating bonding
pads on the structure by electrically conductive "bumps" formed from
solder, conductive epoxy or other suitable material.
LTCC tape is a desirable material for fabricating MCM structures. This tape
includes a mixture of glass and ceramic fillers or recrystallizable glass
which sinters at about 850.degree. C., and exhibits a thermal expansion
similar to alumina. The low-temperature processing is compatible with air
fired resistors and precious metal thick film conductors such as gold,
silver or their alloys. It also allows for the processing of base metals
such as copper in a nitrogen or reducing atmosphere. A general treatise on
LTCC technology is provided in Vitriol et al., "Development of a Low
Temperature Cofired Multi-layer Ceramic Technology", ISHM Proceedings,
1983, pages 593-598. An example of an LTCC circuit package is described in
U.S. Pat. No. 4,899,118 to Polinski, Sr., assigned to Hughes Aircraft
Company, the assignee of the present invention.
A limitation of the present LTCC MCM technology is in the area occupied by
the plural IC chips. It would be highly desirable to be able to reduce the
area requirements for individual chips, and thus free up real estate for
additional circuitry.
One approach to reducing the area required per chip has been to stack
multiple chips vertically in a 3-D arrangement. An example of this
approach is the DPS1MS8A3 CMOS SRAM Module by Dense-Pack Microsystems,
Inc. In this product, sealed circuit modules are stacked and mounted on PC
(printed circuit) boards. A custom fabricated die is required, with
input/output (I/O) contacts located across the center of the chip, rather
than around its periphery as in the great majority of chip configurations.
All of the interconnects between adjacent modules are made by solder along
the outer surfaces of the modules, where they can easily be damaged. The
modules are formed from high temperature cofired ceramic (HTCC) material,
and thus are not compatible with other processes that cannot withstand
high temperatures. Also, they are designed for printed circuit board
applications only.
Another 3-D circuit package is the SRAM Short Stack.TM. by Irvine Sensors
Corporation of Costa Mesa, Calif. In fabricating this package, an
expensive lapping process is used to smooth the sides of the individual
chips to be stacked, and a metallization is added to each die to extend
its contact pads out to the sides of the chip. The chips are then glued
together vertically, with exposed and vulnerable interconnects extending
along the outside of the stack. A particular disadvantage of this product
is that the entire stack fails in the event a single chip within the stack
is bad. Once the stack has been assembled, it cannot later be taken apart
to replace a bad chip and then reassembled. A single bad chip thus results
in the loss of the entire stack.
SUMMARY OF THE INVENTION
The present invention seeks to provide a 3-D IC chip stack that provides a
significant area savings compared to 2-D arrays, is compatible with the
benefits of LTCC construction, is compatible with standard IC chips that
do not require any special fabrication, can employ internal interconnects
that are protected from outside damage, and allows an individual bad chip
to be replaced without losing the remainder of the chips.
These goals are achieved by vertically stacking a plurality of discrete
dielectric tape chip carriers. Each carrier includes a floor formed from a
plurality of dielectric tape layers, a cavity bounded by at least one
additional tape layer above the floor, an IC chip lodged in the cavity,
electrical routing that extends through the carrier body, and electrical
connectors that connect the chip circuitry to its carrier's routing.
Electrical interconnects are provided between the routings for adjacent
carriers, and contacts are provided on the stack for external connections.
In particular embodiments the intercarrier interconnects extend through the
side walls that surround the chip cavity of their respective carriers, and
include conductive contacts that mechanically secure the carriers to each
other. Multiple chip carriers can also be provided in a horizontal array
at one or more of the carrier levels, with the routings for chips on the
same level interconnected with each other. The stacks can be used inside
MCM/hybrid circuits, or mounted directly on PC boards in either flip-chip,
wire bond or leaded configurations. Within each carrier the chips can also
be mounted by various methods, including flip-chip and wire bond. For wire
bonded chips, thermally conductive dielectric spacers that leave enough
peripheral area for the wire bonds can be provided between the exposed
chip surfaces and the undersides of the next upper carriers to assist in
heat dissipation. Other heat dissipation techniques include thermally
conductive vias that extend through the floor of each carrier in the
stack, and the use of a metal heat sink for the floor of the lowermost
carrier. Hermetic sealing can be provided by extending the side walls of
the top carrier up above the chip level, and providing a hermetically
sealed lid.
These and other features and advantages of the invention will be apparent
to those skilled in the art from the following detailed description, taken
together with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a sectional view of a flip-chip embodiment of the invention;
FIG. 2 is a plan view illustrating metallized routing on an LTCC layer in
the floor of a chip carrier;
FIG. 3 is a plan view illustrating interconnected chips on a common carrier
level;
FIG. 4 is a sectional view of a wire bond embodiment of the invention;
FIG. 5 is a fragmentary sectional view showing a thermal via heat
dissipation technique that can be used with the invention; and
FIG. 6 is a fragmentary sectional view showing another heat dissipation
technique.
DETAILED DESCRIPTION OF THE INVENTION
Memory circuits currently account for approximately 60% of a typical MCM's
surface area. The present invention provides a 3-D stacking configuration
that allows circuits such as memories to be packaged in considerably less
surface area; an area reduction of approximately two-thirds can be
achieved with a three-high stack. The new technique is compatible with
both standard and custom dies with peripheral I/Os, and can be used
without special post processing. It allows currently available IC chips to
be handled, tested, pre-burned-in and stacked to obtain both higher
density and higher yields. Since most current MCMs have twenty memory
chips and approximately three to six high I/O count gate arrays, there is
a considerable potential for savings in surface area occupied by the
chips. (The term "chip" as used herein includes both raw dies and packaged
IC chips.)
An application of the invention to a flip-chip configuration is illustrated
in FIG. 1. Only two vertically stacked chips 2 and 4 are illustrated,
although in practice considerably more chips could be stacked. The chips
are typically formed from silicon, although other semiconductor materials
could also be used.
A separate carrier is provided for each chip to facilitate the stacking,
and to provide I/O connections for the chips. In the illustration of FIG.
1, the upper chip 2 is lodged in carrier 6, while the lower chip 4 is
lodged in a separate carrier 8.
Each carrier is formed from a plurality of stacked layers of dielectric
tape, preferably an LTCC tape such as DuPont Screen Tape.RTM. No. 951AT.
Other types of dielectric tape could also be used. For example, high
temperature cofired ceramic (HTCC) tape can also support electrical
routing, but refractory metals with a higher resistivity are required
because of the higher sintering temperatures that must be withstood.
Laminates such as polyimide, fiberglass or plastic are also candidates,
although they exhibit poor thermal conductivity and are not hermetic.
Aluminum nitrite (AlN) has a high thermal conductivity, and may be a
desirable material for practicing the invention. While the remainder of
this specification describes the invention in terms of LTCC, it should be
understood that other types of dielectric tape might be used instead,
depending upon the particular application.
Since the two carriers 6 and 8 are similar in construction, only the upper
one 6 will be described in detail. It consists of a floor 10 formed from a
plural number of stacked LTCC layers, and a side wall 12 that is formed
from at least one LTCC layer and surrounds the chip 2. Three LTCC layers
14, 16 and 18 are illustrated for the floor. The surface of each tape
layer would normally include a metallized routing pattern (illustrated in
FIG. 2), and can also have passive electrical components 20 such as
resistors, inductors and/or capacitor plates. The side wall 12 is
illustrated as including two LTCC layers 22, 24; the number of layers used
in any given application will normally depend upon the thickness of the IC
chip 2.
The electrical circuitry is formed on the underside of the chip 2, which is
flip-chip mounted to the upper surface of the upper floor LTCC layer 14.
The chip is both electrically connected and mechanically secured to the
carrier by means of conductive epoxy or solder "bumps" 26 between
conductive pads on the underside of the chip and corresponding pads on the
upper surface of the cavity floor. Other epoxies can be applied to the
nonelectrical contact areas to aid in thermal and mechanical attachment if
required. Individual floor pads can provide a connection either to the
routing on the surface of the upper floor layer 14, or to routings and/or
electrical components on the lower floor layers 16, 18 by means of vias
28. This type of chip mounting to a layered LTCC substrate is disclosed
for a two-dimensional package in U.S. Pat. No. 4,899,118.
The LTCC layers are each about 90 micrometers (microns) thick after firing.
An IC chip is typically manufactured about 500-600 microns thick, which
allows it to withstand the manufacturing process. However, the chip can be
lapped from its rear surface, using standard lapping techniques, in either
the wafer or the die state, to a thickness on the order of one LTCC layer.
Such lapping allows the height of the carrier, and thus of the overall
stack, to be reduced, and thereby accommodate a greater number of chips
and carriers.
The flip-chip mounted IC chip 2 is lodged within a cavity 30 that is formed
by the floor 10 and the surrounding side walls 12. Multiple carriers with
similarly mounted chips are vertically stacked as illustrated in FIG. 1.
The electrical routing for each carrier is brought out along the surfaces
of the floor layers to the side wall region, where connections between
adjacent carriers are made. In the embodiment of FIG. 1, vertically
aligned vias 32 extend through the side walls and floors of each carrier,
with the vias for adjacent carriers mechanically and electrically
connected by flip-chip connector bumps 34 in a manner similar to the
connection of the IC chips to the floors of their respective carriers. The
connector bumps 34 provide a mechanical integrity that holds the stack
together. The exposed ends of the vias 32 serve as contact pads for the
bumps.
The IC chips are preferably lapped so that they extend upward to contact
the underside of the floor for the next higher carrier. This assists in
heat dissipation through the stack. Memory architectures typically call
for only one memory chip being activated at a time; the heat generated by
whichever chip is activated at a particular time can thus transfer heat
through the stack. Since memory chips commonly share data and address
lines, all but one or two of the intercarrier interconnects 32 would
typically extend through the entire stack and be connected to each chip
within the stack.
Once it has been fabricated, the stack can be connected to a substrate,
such as a common carrier with a matching temperature coefficient of
expansion. The mechanical connections are preferably made by means of
solder bumps or conductive epoxy 38 between contacts for the vias 32 on
the stack, and corresponding contact pads on the common carrier 36.
An illustrative electrical routing scheme formed in the floor 40 of one of
the carriers is illustrated in FIG. 2. The routing consists of metallized
traces 42 that extend between both the peripheral intercarrier
interconnect vias 32 and the vias 28 that connect to the chips. The
routing for a number of floor layers is superimposed in the illustration
of FIG. 2; crossovers within any single floor layer would normally be
avoided. The routing can be used to provide both I/O connections for the
various chips, and internal connections for a given chip.
To fabricate a carrier, holes, cavities and/or slots are punched into
individual tape layers to accommodate the IC chip and any other desired
component such as capacitors. Routings and vias are screened onto the
various layers as necessary. Silver is preferably used for the
metallization, in contrast to the high resistivity refractory metals that
must be used with the Dense-Pack Microsystems, Inc. chip stack mentioned
above. The tape layers are then stacked in a frame that holds the vias in
alignment, pressed together, and then fired in a conventional manner so
that they shrink and adhere to each other, forming an integral atomic
structure. Several carriers can be formed simultaneously at different
locations on the same tape layers in this manner. After firing the unit is
either scribed and broken apart into individual carriers, or left whole as
a multi-chip carrier.
IC dies are then mounted in the carrier cavities. If the die is to be
thinned, it is either thinned before being mounted or, in the case of
flip-chip configurations, the chip and carrier can be thinned together
after the chip has been mounted. A conventional lapping process is used
that both thins the chip and provides a smooth surface for good thermal
contact with an overlying carrier. After mounting the chip is subjected to
the normal test, burn-in and other completion procedures. Multiple
carriers are then stacked vertically and connected to each other by the
epoxy or solder bumps 34. In mounting the chips to their respective
carriers, and also in stacking the carriers together, the application of
the conductive epoxy or solder should be controlled to avoid inadvertent
short circuits between adjacent contacts.
If a bad chip is identified after the stack has been assembled, it can be
removed simply by heating the stack to the epoxy curing temperature,
separating the carriers, removing the bad chip from its carrier and
replacing it with a new chip, and then reassembling the stack. This avoids
a loss of the entire stack.
FIG. 3 illustrates a multi-chip carrier in which individual chips 44 are
lodged within respective cavities 46 in an assembly of LTCC layers 48. The
LTCC layers provide a floor and sidewall for each of the chip cavities, as
described above. Interconnections between chips can be made by metallized
routings 50 that extend on one or more LTCC layers between the routings
under the chips.
An application of the invention to wire bonded chips is illustrated in FIG.
4. Again, only two chips 52, 54 and their respective carriers 56, 58 are
illustrated, although additional chips and carriers could be provided in
the stack. The carriers are formed from LTCC tape in a manner similar to
the carriers of FIG. 1, with the chips 52, 54 lodged in respective carrier
cavities 60, 62 above floors formed by underlying LTCC layers.
In this application, the carrier side walls are preferably formed with
inward directed shelves 64, 66 at the level of the upper chip surface.
Corresponding wire bond pads 68 are provided in the peripheral chip areas,
and on the side wall shelves. The chip wire bond pads connect to the chip
circuitry, while the side wall pads are brought out to the exterior of the
carrier by electrical routing 70 that extends along the upper surface of
the LTCC layer forming the shelf. While this embodiment could be
implemented with vertically aligned vias 32 within the carrier side walls
as in FIG. 1, the routing 70 is illustrated as being electrically
connected to corresponding wire bond pads 72 on an outer peripheral shelf
of the lowermost carrier by respective metallization traces 74 that extend
down the exteriors of the carriers. Corresponding wire bond pads 68 inside
the carriers are connected by respective wires 76, while the wire bond
pads 72 outside the lowermost carrier are connected to corresponding pads
78 on a common carrier or PC board 80 or other mounting surface by
respective wire bonds or brazed leads 82. Just as internal vias 32 could
be substituted for the external connector traces 74 in FIG. 4, external
connector traces could be used instead of internal vias in the embodiment
of FIG. 1. Alternates to wirebonds or leads for connecting the bottom
carrier to the substrate include ball grid arrays and peripheral arrays.
If desired, electrical routing can also be provided in the floor of each
carrier and electrically connected to the chip circuits through vias (not
shown) that extend up through the side walls of the cavity, and then
through associated wire bond connections. The carriers are held together
by a suitable adhesive or solder that can preferably be released at a
temperature low enough to avoid damage to the chips, should access to a
chip be desired after the stack has been assembled.
To assist in extracting heat from the assembly, dielectric spacers formed
from a thermally conductive material such as beryllium oxide or aluminum
nitride can extend up from each chip to the underside of the carrier for
the next upper chip. The spacers 84 should be small enough to leave room
for the wire bond contacts 68 around the peripheries of the chips, but
large enough in area to provide for effective thermal transfer. Their
upper surfaces are preferably lapped to provide a good contact with the
next higher carrier. If hermetic sealing of the chips is desired, the side
walls of the uppermost carrier 56 can be extended upward, and an air-tight
lid 86 hermetically attached over the carrier.
FIGS. 5 and 6 illustrated additional heat dissipation techniques that can
be used to extract heat from the stack, the lowermost carrier of which is
shown mounted on a substrate 88 such as a PC board. In FIG. 5, metallic
vias 90 are provided through the LTCC layers which form the floor 92 under
an IC chip 94. The via in at least one LTCC layer is staggered with
respect to the vias in adjacent layers, and connected to the vias in the
adjacent LTCC layers by metallization 96 on the LTCC layer surfaces. This
allows for hermetically sealed thermal connections between the chip and
the substrate 88, and also provides electrical connections to routings in
the floor layers. The technique is similar to that disclosed in U.S. Pat.
No. 4,899,118.
In FIG. 6 a metallic heat sink 98 is used as the floor of the carrier for a
wire bond chip 100. Wire bond connections to the chip are made through the
carrier's LTCC side walls 102, as in FIG. 4. The chip 100 sits directly
upon the heat sink floor 98 to dissipate heat.
While several embodiments of the invention have been shown and described,
numerous variations and alternate embodiments will occur to those skilled
in the art. For example, the chips can be connected to their respective
carriers by means other than flip-chip or wire bond. Various lead
configurations, tape automated bonding (TAB) and ribbon bonds could be
used, depending upon the particular application. Accordingly, it is
intended that the invention be limited only in terms of the appended
claims.
* * * * *
|
|
|
|
|
|
|
Description |
|
