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Description  |
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BACKGROUND
The present invention relates generally to processing methods of forming
high density multichip interconnect (HDMI) structures, and more
particularly, to methods of forming two-sided flexible HDMI decals
comprising flexible fine line interconnect structures.
Traditional prior art relating to the present invention is provided by a
double sided PC board or double sided flexible interconnect circuits.
These prior art interconnect structures are manufactured with equipment
and processes that limit their line densities. Neither use high
performance, high temperature, low coefficient of thermal expansion
polyimide dielectric polymer materials.
Traditional flexible interconnect manufacturing techniques are limited in
their material selection, thermal capability and line densities. New
generation integrated circuits, liquid crystal displays, three dimensional
electronic structures and infrared detectors impose ever greater demands
for higher line density, improved thermal durability, greater
environmental stability and lower cost than can be provided by the
conventional interconnect structures. Thus, it would be an improvement to
have interconnect structures that provide high two-sided interconnect
density at reduced cost and with controlled parasitic effects while
providing improved thermal and environmental stability compared to
conventional interconnect structures. U.S. patent application Ser. No.
08/629,956, filed Apr. 8, 1996, entitled "HDMI Decal and Fine Line
Flexible Interconnect Forming Methods", assigned to the assignee of the
present invention discloses methods of forming single-sided high density
multilayer interconnect (HDMI) structures. This invention produces
single-sided HDMI structures that are useful in producing
three-dimensional flexible cables, membrane IC test boards and power
devices, and the like that require free line metallized conductors. The
present invention improves upon this particular invention.
Accordingly, it is an objective of the present invention to provide for a
method of forming two-sided flexible HDMI decals comprising two-sided
flexible fine line HDMI interconnect structures.
SUMMARY OF THE INVENTION
To meet the above and other objectives, the present invention provides for
methods of forming two-sided high density multilayer interconnect (HDMI)
structure on a rigid carrier and subsequently releasing the two-sided
interconnect to form a flexible decal with interconnected metallization on
both sides of the structure. The present invention improves upon methods
disclosed in the above-cited U.S. Patent Application entitled "HDMI Decal
and Fine Line Flexible Interconnect Forming Methods", assigned to the
assignee of the present invention. The contents of this application are
incorporated herein by reference in its entirety.
In the present invention, a carrier, such as quartz, for example, is
provided that does not absorb UV or laser radiation, and a release layer,
which may comprise a polyimide layer, for example, is formed on the
carrier. A two-sided flexible high density multilayer interconnect (HDMI)
structure is then fabricated on the release layer. The two-sided flexible
HDMI structure is fabricated in a manner that forms a second set of
contact pads adjacent to the release layer. After fabrication of the
two-sided flexible HDMI structure, the release layer is processed to
release (delaminate) and remove it and the two-sided flexible HDMI
structure from the carrier.
The release layer of the two-sided flexible HDMI structure is then
processed to expose the bottom set of contact pads. This may be achieved
in a number of ways. A first way is to temporarily bond the top surface of
the decal to an inert flat plate using a temporary adhesive. The decal is
then released or delaminated from the carrier to expose bottom surface of
the decal, which comprises the polyimide release layer. Vias are formed in
the release layer to expose contacts to the bottom set of contact pads.
Additional metal is then deposited and patterned on the release layer that
contacts the bottom set of contact pads through the vias. This forms the
bottom pad layer of the decal to which connections may be made.
A second way to process the two-sided flexible HDMI structure is to release
it from the carrier. Then, the release layer is removed to expose the
bottom set of contact pads. The exposed bottom set of contact pads may be
used as is or may have additional metal layers deposited and patterned for
the bottom pad layer of the decal. This procedure may also use the inert
flat plate to temporarily bond the top surface of the decal during
processing of the bottommost layers thereof.
The two-sided flexible HDMI interconnect structure fabricated in accordance
with the present invention may be used in applications that demand high
density, low profile, low weight interconnect structures. The present
invention produces the highest two-sided interconnect density presently
available in a structure that has improved thermal and environmental
stability.
BRIEF DESCRIPTION OF THE DRAWINGS
The various features and advantages of the present invention may be more
readily understood with reference to the following detailed description
taken in conjunction with the accompanying drawings, wherein like
reference numerals designate like structural elements, and in which:
FIG. 1 is a cross sectional side view showing fabrication of a two-sided
flexible high density multilayer interconnect structure prior to release
from its carrier using methods in accordance with the principles of the
present invention;
FIGS. 2a, 2b and 2c show fully fabricated two-sided flexible high density
multilayer interconnect structures;
FIGS. 3a-3i are flow diagrams illustrating details of various methods in
accordance with the principles of the present invention.
DETAILED DESCRIPTION
Referring to the drawing figures, FIG. 1 is a cross sectional side view
showing fabrication of a two-sided flexible high density multilayer
interconnect (HDMI) structure 10 or HDMI decal 10 fabricated Using methods
20 in accordance with the principles of the present invention. The present
methods 20 may be implemented using HDMI processes disclosed in U.S. Pat.
No. 5,034,091 and U.S. Pat. No. 5,311,404, in addition to methods
disclosed in the above-cited U.S. Patent Application entitled "HDMI Decal
and Fine Line Flexible Interconnect Forming Methods", for example, all of
which are assigned to the assignee of the present invention. The
techniques disclosed in these references may be adapted to produce the
multilayer interconnect structure 10 on a rigid non-UV or non-laser
absorbing carrier 11 as shown in FIG. 1.
The flexible HDMI structure 10 is fabricated on a relatively large carrier
11, typically having dimensions on the order of two feet by two feet. In
one embodiment of the present invention, the carrier 11 may comprise an
ultraviolet transparent substrate 11 or wafer 11, such as quartz, for
example, or may comprise a silicon wafer 11 or a metal carrier, for
example, depending upon the release technique that is to be used to remove
or release the flexible HDMI structures 10 from the carrier 11.
The carrier 11 has a release layer 12 formed or otherwise deposited
thereon. When the ultraviolet transparent substrate 11 is used as the
carrier 11, a polyimide layer 12 is deposited as the release layer 12.
When the silicon substrate 11 is used as the carrier 11, a metal or
silicon dioxide layer 12 is deposited as the release layer 12. The metal
release layer 12 may be comprised of titanium or tungsten, or mixtures
thereof, for example.
The two-sided flexible HDMI structure 10 is comprised of a plurality of
dielectric layers 15 having free line metallization patterns 13 and vias
14 formed therein that terminate at an upper set of contact pads 17 on the
top surface of the structure 10. The free line metallization patterns 13
include, but are not limited to, a bottom contact pad layer 13a, pad
routing layers 13b, a ground layer 13c, an X-direction signal layer 13d, a
Y-direction signal layer 13e, a power layer 13f and an upper contact pad
layer 13g. The upper contact pad layer 13g has a plurality of bond pads 17
coupled thereto that are used to connect to electronic components (not
shown).
For example, each of the HDMI structures 10 may comprise dielectric layers
15 comprising polyimide having aluminum or copper fine line interconnects
13 and vias 14 formed therethrough that provide signal paths from the
upper set of bond pads 17 disposed at the surface of the two-sided HDMI
structure 10 to the bottom contact pad layer 13a. The bottom contact pad
layer 13a is connected to a lower set of bond pads 13a (FIGS. 2a and 2b)
that are connected to electronic components (not shown). The plurality of
two-sided HDMI structures 10 are formed on the carrier 11 and release
layer 12 using MCM-D (multichip module - dielectric) processing techniques
employed by the assignee of the present invention. Processing that may be
used to fabricate the two-sided HDMI structures 10 is described in U.S.
Pat. No. 5,034,091, entitled "Method of Forming an Electrical Via
Structure", and assigned to the assignee of the present invention, which
is incorporated herein by reference in its entirety.
Subsequent to fabrication of the two-sided HDMI structures 10, the release
layer 12 is processed to release or remove one or more fabricated
two-sided HDMI interconnect structures 10 from the carrier 11. FIGS. 2a
and 2b show fully fabricated two sided flexible high density multilayer
interconnect structures (without electronic components) after it is
released from the carrier 11. Once the plurality of two-sided HDMI
structures 10 are formed, in the case where the ultraviolet transparent
substrate 11 is used as the carrier 11, a short wavelength ultraviolet
radiation source 19, which is programmable and controlled, is used to
release individual ones of the two-sided HDMI structures 10. A
programmable pick and place machine may be used to physically remove the
two-sided HDMI structures 10 once they are released from the carrier 11.
Alternatively, a flood beam ultraviolet radiation source 19 may be used to
release many or all of the two-sided HDMI structures 10 from the
ultraviolet transparent substrate 11 or carrier 11. The ultraviolet
radiation source 19 is caused to radiate ultraviolet radiation through the
ultraviolet transparent carrier 11 and onto the release layer 12. For
example, an ultraviolet laser may be used to selectively irradiate one of
the two-sided HDMI structures 10 to release it from the release layer 12.
The ultraviolet radiation (photons) from the ultraviolet radiation source
19 interacts with the polyimide release layer 12 adjacent to the carrier
11 and ruptures or otherwise breaks the adhesive bond therebetween. This
permits the two-sided HDMI structures 10 to be lifted off of the carrier
11 using the programmable pick and place machine or other tool, for
example. Multiple two-sided HDMI structures 10 may be released from the
carrier 11 using a wide area ultraviolet radiation source 19 in a similar
manner.
In cases where the carrier 11 comprises a silicon substrate 11, a titanium
or tungsten or mixture thereof metal layer 12, or a silicon dioxide layer
12 is used as the release layer 12. An appropriate wet etching procedure
is used to totally release the two-sided HDMI structures 10 from the
release layer 12. Wet etching procedures are well known to those skilled
in the art that will release the HDMI structures 10.
Referring to FIG. 2a, the release layer 12 of the two-sided flexible HDMI
structure 10 must be processed to expose the bond pads at the bottom
thereof. This may be achieved by temporarily bonding the top surface of
the two-sided flexible HDMI structure 10 to an inert flat plate 32 using a
temporary adhesive 31. The two-sided flexible HDMI structure 10 is then
released or delaminated from the carrier to expose bottom surface of the
structure 10 (the polyimide release layer 12). Vias 16 are formed through
the polyimide release layer 12 to expose the bottom set of bond pads 13a.
Additional metal is then deposited in the vias 16 and a bottom set of
contact pads 18 are formed for the two-sided flexible HDMI structure 10 to
which connections may be made.
Referring to FIG. 2b, the second way is to release the two-sided flexible
HDMI structure 10 from the carrier 11. Then, the release layer 12 is
removed to expose the bottom set of bond pads 13a. The exposed bottom set
of bond pads 13a may be used as is to provide a bottom set of contact pads
18 for the flexible HDMI structure 10 to which connections may be made.
This procedure may also use the inert flat plate 32 that is temporarily
bonded to the top surface of the two-sided flexible HDMI structure 10
during processing of the bottommost layers thereof. Because its use is
optional, the inert flat plate 32 and adhesive 31 are shown in dashed
lines in FIG. 2b.
Referring to FIG. 2c, the third way is to release the two-sided flexible
HDMI structure 10 from the carrier 11. Then, the release layer 12 is
removed to expose the bottom set of bond pads 13a. The exposed bottom set
of bond pads 13a are then further processed to provide a bottom set of
contact pads 18 for the flexible HDMI structure 10. This may be
accomplished by depositing additional metal layers that contact the
exposed bottom set of bond pads 13a, thusly forming the bottom set of
contact pads 18 of the two-sided flexible HDMI structure 10 to which
connections may be made. This procedure may also use the inert flat plate
32 that is temporarily bonded to the top surface of the two-sided flexible
HDMI structure 10 during processing of the bottommost layers thereof.
Because its use is optional, the inert flat plate 32 and adhesive 31 are
shown in dashed lines in FIG. 2c.
The two-sided flexible HDMI structure 10 may be fully populated prior to
exposing the bottom side thereof to a short wavelength high energy laser
beam, or a short UV broad spectrum high intensity flash lamp that
vaporizes the polyimide release layer 12 and exposes the set of bond pads
adjacent the bottom side of the structure 10.
For the purposes of completeness, FIGS. 3a-3i show flow diagrams
illustrating methods 20 in accordance with the present invention for
forming two-sided flexible HDMI structures 10 on a carrier 11 and
subsequently releasing them either individually or in total from the
carrier 11. The present methods 20 are as follows.
Referring to FIG. 3a, a first method 20a comprises the steps of providing
21 a transparent carrier 11 that is transparent to ultraviolet radiation,
and forming 22 a release layer 12 on the transparent carrier 11. Then
two-sided flexible high density multilayer interconnect structures 10 are
then fabricated 23 on the release layer 12. The top surface of the
two-sided flexible HDMI structure 10 is then temporarily bonded 24 to an
inert flat plate 32 using a temporary adhesive 31. The two-sided flexible
HDMI structure 10 is then released 25 or delaminated 25 from the carrier
12 to expose the release layer 12. A laser is then used to form 26 vias 16
through the release layer 12 to expose the bottom set of bond pads 13a. A
bottom set of contact pads 18 is formed for the two-sided flexible HDMI
structure 10 by depositing 27 additional metal in the vias 16 and on the
exposed bottom surface of the carrier 12.
Referring to FIG. 3b, a second method 20b comprises the steps of providing
21 a carrier 11, such as a silicon carrier 21a, forming 22 a release layer
12, such as a metal (titanium or tungsten or mixture thereof) release
layer 12, on the carrier 11, fabricating 23 two-sided flexible high
density multilayer interconnect structures 10 on the metal release layer
12. The top surface of the two-sided flexible HDMI structure 10 is then
temporarily bonded 24 to an inert flat plate 32 using a temporary adhesive
31. The two-sided flexible HDMI structure 10 is then released 25 or
delaminated 25 from the carrier to expose the release layer 12. A laser is
then used to form 26 vias 16 through the release layer 12 to expose the
bottom set of bond pads 13a. A bottom set of contact pads 18 is formed 27
for the two-sided flexible HDMI structure 10 by depositing 27 additional
metal in the vias 16 and on the exposed bottom surface of the carrier 12.
Referring to FIG. 3c, a third method 20c comprises the steps of providing
21 a carrier 11, such as a silicon carrier 11, forming 22 a release layer
12, such as a silicon dioxide release layer 12, on the rigid carrier 11,
fabricating 23 two-sided flexible high density multilayer interconnect
(HDMI) structures 10 on the release layer 12. The top surface of the
two-sided flexible HDMI structure 10 is then temporarily bonded 24 to an
inert flat plate 32 using a temporary adhesive 31. The two-sided flexible
HDMI structure 10 is then released 25 or delaminated 25 from the carrier
to expose the release layer 12. A laser is then used to form 26 vias 16
through the release layer 12 to expose the bottom set of bond pads 13a. A
bottom set of contact pads 18 is formed 27 for the two-sided flexible HDMI
structure 10 by depositing 27 additional metal in the vias 16 and on the
exposed bottom surface of the carrier 12.
Referring to FIG. 3d, a fourth method 20d comprises the steps of providing
21 a transparent carrier 11 that is transparent to ultraviolet radiation,
and forming 22 a release layer 12 on the transparent carrier 11. Then
two-sided flexible high density multilayer interconnect structures 10 are
fabricated 23 on the release layer 12, and processed to release 25 the
flexible HDMI structures 10 from the rigid carrier 11. The two-sided
flexible high density multilayer interconnect structures 10 may be
released 25 by irradiating the release layer 12 through the transparent
carrier 11 using an ultraviolet radiation source 19. Then, the release
layer 12 is removed 28 to expose the bottom set of bond pads 13a. The
exposed bottom set of bond pads 13a are used as the bottom set of contact
pads 18 of the flexible HDMI structure 10.
Referring to FIG. 3e, a fifth method 20e comprises the steps of providing
21 a carrier 11, such as a silicon carrier 11, forming 22 a release layer
12, such as a metal (titanium or tungsten or mixture thereof) release
layer 12, on the carrier 11, fabricating 23 two-sided flexible high
density multilayer interconnect structures 10 on the metal release layer
12, and processing the metal release layer 12 to release 25 the two-sided
flexible HDMI structures 10 from the carrier 11, such as by using a wet
etching procedure. Then, the release layer 12 is removed 28 to expose the
bottom set of bond pads 13a. The exposed bottom set of bond pads 13a are
used as the bottom set of contact pads 18 of the flexible HDMI structure
10.
Referring to FIG. 3f, a sixth method 20f comprises the steps of providing
21 a carrier 11, such as a silicon carrier 11, forming 22 a release layer
12, such as a silicon dioxide release layer 12, on the rigid carrier 11,
fabricating 23 two-sided flexible high density multilayer interconnect
(HDMI) structures 10 on the release layer 12, and processing the release
layer 12 to release 25 the two-sided flexible HDMI structures 10 from the
rigid carrier 11, such as by using a wet etching procedure. Then, the
release layer 12 is removed 28 to expose the bottom set of bond pads 13a.
The exposed bottom set of bond pads 13a are used as the bottom set of
contact pads 18 of the flexible HDMI structure 10.
Referring to FIG. 3g, a seventh method 20g comprises the steps of providing
21 a transparent carrier 11 that is transparent to ultraviolet radiation,
and forming 22 a release layer 12 on the transparent carrier 11. Then
two-sided flexible high density multilayer interconnect structures 10 are
fabricated 23 on the release layer 12, and processed to release 25 the
flexible HDMI structures 10 from the rigid carrier 11. The two-sided
flexible high density multilayer interconnect structures 10 may be
released 25 by irradiating the release layer 12 through the transparent
carrier 11 using an ultraviolet radiation source 19. Then, the release
layer 12 is removed 28 to expose the bottom set of bond pads 13a. The
exposed bottom set of bond pads 13a are then further processed 29 to
provide a bottom set of contact pads 18 for the flexible HDMI structure
10. This may be accomplished by depositing 29 additional metal layers that
contact the exposed bottom set of bond pads 13a, thusly forming the bottom
set of contact pads 18 of the two-sided flexible HDMI structure 10 to
which connections may be made.
Referring to FIG. 3h an eighth method 20h comprises the steps of providing
21 a carrier 11, such as a silicon carrier 11, forming 22 a release layer
12, such as a metal (titanium or tungsten or mixture thereof) release
layer 12, on the carrier 11, fabricating 23 two-sided flexible high
density multilayer interconnect structures 10 on the metal release layer
12, and processing the metal release layer 12 to release 25 the two-sided
flexible HDMI structures 10 from the carrier 11, such as by using a wet
etching procedure. Then, the release layer 12 is removed 28 to expose the
bottom set of bond pads 13a. The exposed bottom set of bond pads 13a are
then further processed 29 to provide a bottom set of contact pads 18 for
the flexible HDMI structure 10. This may be accomplished by depositing 29
additional metal layers that contact the exposed bottom set of bond pads
13a, thusly forming the bottom set of contact pads 18 of the two-sided
flexible HDMI structure 10 to which connections may be made.
Referring to FIG. 3i, a ninth method 20i comprises the steps of providing
21 a carrier 11, such as a silicon carrier 11, forming 22 a release layer
12, such as a silicon dioxide release layer 12, on the rigid carrier 11,
fabricating 23 two-sided flexible high density multilayer interconnect
(HDMI) structures 10 on the release layer 12, and processing the release
layer 12 to release 25 the two-sided flexible HDMI structures 10 from the
rigid carrier 11, such as by using a wet etching procedure. Then, the
release layer 12 is removed 28 to expose the bottom set of bond pads 13a.
The exposed bottom set of bond pads 13a are then further processed 29 to
provide a bottom set of contact pads 18 for the flexible HDMI structure
10. This may be accomplished by depositing 29 additional metal layers that
contact the exposed bottom set of bond pads 13a, thusly forming the bottom
set of contact pads 18 of the two-sided flexible HDMI structure 10 to
which connections may be made.
Thus, methods of forming two-sided flexible HDMI decals comprising flexible
fine line interconnect structures has been disclosed. It is to be
understood that the described embodiments are merely illustrative of some
of the many specific embodiments which represent applications of the
principles of the present invention. Clearly, numerous and varied other
arrangements may be readily devised by those skilled in the art without
departing from the scope of the invention.
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