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| United States Patent | 5487999 |
| Link to this page | http://www.wikipatents.com/5487999.html |
| Inventor(s) | Farnworth; Warren M. (Nampa, ID) |
| Abstract | A method for forming contacts for establishing an electrical connection
with contact locations on a semiconductor die is provided. The contacts
are formed as raised members mounted on a compliant substrate. Each
contact includes a rough textured surface having asperities adapted to
penetrate the contact location on the die to a limited penetration depth.
The height of the asperities is between about 1000.ANG. to 10,000.ANG..
The textured surface and asperities are formed by electroplating a rough
metal layer on a raised metal contact or by etching a surface of a raised
metal contact. In an illustrative embodiment the contacts comprise
microbumps formed on a compliant polyimide substrate. For forming an
interconnect suitable for establishing a temporary electrical connection
with an unpackaged semiconductor die, the polyimide substrate is attached
to a rigid substrate, such as silicon, having a coefficient of thermal
expansion that matches that of a silicon die. The interconnect can then be
used with a carrier for testing the unpackaged die. |
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Title Information  |
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Drawing from US Patent 5487999 |
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Method for fabricating a penetration limited contact having a rough
textured surface |
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| Publication Date |
January 30, 1996 |
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| Filing Date |
November 22, 1994 |
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| Parent Case |
CROSS REFERENCE TO RELATED APPLICATIONS
This application is a continuation-in-part of application Ser. No.
08/073,005 filed Jun. 7, 1993, now U.S. Pat. No. 5,408,190, which is a
continuation-in-part of applications Ser. Nos. 07/709,858 filed Jun. 4,
1991, abandoned; 07/788,065 filed Nov. 5, 1991, now U.S. Pat. No.
5,440,240; and, 07/981,956 filed Nov. 24, 1992.
This application is related to copending applications Ser. Nos. 08/124,899
filed Sep. 21, 1993; 08/046,675 filed Apr. 14, 1993, now U.S. Pat. No.
5,367,253; 08/073,003 pending Jun. 7, 1993; 08/120,628 filed Sep. 13,
1993; 08/192,023 filed Feb. 3, 1994; 07/896,297 filed Jun. 10, 1992 now
U.S. Pat. No. 5,424,652; 08/192,391 filed Feb. 3, 1994; and, 08/137,675
filed Oct. 14, 1993, now abandoned. |
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Title Information |
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Description |
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FIELD OF THE INVENTION
This invention relates to semiconductor manufacture and to testing of
semiconductor dice. More particularly, this invention relates to a method
for fabricating a penetration limited contact adapted to establish an
electrical connection with a contact location on a semiconductor die.
BACKGROUND OF THE INVENTION
Unpackaged or bare semiconductor dice are being increasingly used in the
manufacture of electronic devices that employ multi-chip modules (MCM).
These unpackaged dice are mounted directly to a substrate such as a
printed circuit board. With unpackaged dice, semiconductor manufacturers
are required to supply dice that have been tested and certified as known
good die. Known good die (KGD) is a collective term that denotes
unpackaged die having the same quality and reliability as the equivalent
packaged product.
For testing an unpackaged die, an electrical pathway must be established
between the unpackaged die and external test circuitry. An interconnect is
typically used to form a temporary electrical connection with the die. The
interconnect includes the contact structure that physically contacts and
forms an electrical connection with contact locations on the die.
These contact locations are typically die pads (e.g., bond pads or test
pads) located on the face of the die in electrical communication with
integrated circuitry. Die pads are relatively small in size and are
closely packed on the face of the die. As an example, bond pads are
typically polygonal in shape (e.g., square, triangular) and are only about
100 .mu.m on a side. The spacing between bond pads is on the order of 50
to 100 .mu.m or less. The contact structure for an interconnect must
therefore be precisely formed to accommodate the size and spacing of the
bond pads.
In addition, the contact structure on the interconnect preferably forms a
low-resistance ohmic electrical connection with the contact location. An
ohmic electrical connection is one in which the voltage appearing across
the connection is proportional to the current flowing for both directions
of current flow. In order to form a low-resistance ohmic connection, a
contact structure must penetrate an oxide layer covering the bond pad. An
aluminum bond pad for instance, will typically include a native oxide
layer which forms during the manufacturing process. This oxide layer,
which may be about 100.ANG. or more in thickness, must be either
penetrated or wiped away to establish an electrical connection that is
ohmic. At the same time, however, damage to the bond pad must be kept to a
minimum. A bond pad may only be about 1.mu. thick and is thus relatively
easy to damage.
One well known contact structure used for forming interconnects and other
connection systems is the needle probe. Needle probes however, exhibit a
variety of shortcomings. In particular, needle probes are susceptible to
damage, misalignment and rapid loss of contact force. In addition, needle
probes may not provide uniform contact to vertically misaligned pads and
may damage the pads. Needle probes also require extensive maintenance and
adjustment. All of these problems are compounded by the higher integration
of semiconductor dice and a corresponding decrease in the size and pitch
of bond pads. This has led to the recent development of other connection
systems for testing semiconductor dice at both the wafer level and the die
level.
Some recently developed connection systems include compliant contact
structures adapted to flex to accommodate variations in the planarity of
the die pads. As an example, U.S. Pat. No. 5,264,787 to Worth et al.
describes an interconnect that includes an array of metal plated contacts
formed on a flexible membrane. This type of contact is manufactured by
Packard-Hughes under the trademark Gold Dot.TM.. U.S. Pat. Nos. 5,103,557
and 5,323,035 to Leedy disclose other contact structures that are mounted
on a flexible substrate or membrane. In addition, U.S. Pat. No. 5,207,585
to Byrnes et al. discloses an interconnect that includes a flexible
interface pellicle having electrodes for contacting raised conductive
bumps on a die.
Although some prior art interconnects compensate for variations in-the
vertical location of pads on a die, there can still be problems in
piercing an oxide layer covering the contact to form an electrical
connection. Some interconnects utilize an arrangement in which the
flexible membrane for mounting the contacts is tensioned prior to
engagement with the die. When the tension is released, the contacts move
across the die pads and scrub away the oxide layer to establish an
electrical connection. Such a scrubbing action however increases the
complexity of the interconnect and may damage the die pads.
One recently developed technique for preventing damage to a die pad, while
establishing an electrical connection, is to limit the penetration depth
of a contact into the die pad. U.S. Pat. No. 5,326,428 to Farnworth et
al., the present applicant, discloses such a penetration limited contact
structure. With such a contact structure, raised silicon contact members
are formed on a silicon substrate. Each raised contact member includes a
raised projection, such as a point or knife edge, that penetrates the die
pad to establish an electrical connection. The penetration depth however,
is limited by the dimensions of the projection and by a stop plane
provided by a top surface of the contact member.
The present invention is directed to an improved contact structure that
also includes a self limiting feature. The contact structure is especially
useful for forming interconnects and other connection systems for
semiconductor dice. The improved contact structure is mounted on a
compliant substrate and is adapted to penetrate a contact location on a
semiconductor die to a limited penetration depth to establish an
electrical connection.
OBJECTS OF THE INVENTION
Accordingly, it is an object of the present invention to provide a method
for forming an improved contact structure suitable for establishing an
electrical connection with contact locations on a semiconductor die.
It is yet another object of the present invention to provide a method for
forming an oxide penetrating contact structure on a compliant substrate.
It is a further object of the present invention to provide a method for
forming an improved contact structure having a rough textured surface
adapted to penetrate a contact location on a die but with a limited
penetration depth.
It is a still further object of the present invention to provide a method
for forming an improved contact structure suitable for forming
interconnects useful in the testing of unpackaged semiconductor dice.
Other objects, advantages and capabilities of the present invention will
become more apparent as the description proceeds.
SUMMARY OF THE INVENTION
In accordance with the present invention, a method for forming a contact
structure for establishing an electrical connection with contact locations
on a semiconductor die is provided. The contact structure, simply stated,
includes a raised projection, such as a microbump, mounted on a compliant
substrate and having a rough textured surface. The rough textured surface
includes raised asperities adapted to penetrate a contact location such as
a die pad. At the same time, a penetration depth into the contact location
is limited by the dimensions of the asperities. By way of example, for a
contact structure formed as a convex microbump having a diameter of about
30.mu., the asperities will have a height of about 1,000.ANG. to
10,000.ANG..
A method for forming the contact structure, simply stated, comprises
fabricating a raised contact on a compliant substrate, and then forming a
rough textured surface on the raised contact. The rough textured surface
can be formed by depositing a rough metal layer on the raised contact
using an electrolytic plating process. Alternately the rough textured
surface can be formed by etching the raised contact to produce a rough
surface.
For forming a rough textured surface on the contact using an electrolytic
plating process, the raised contact is submerged in a tank containing an
electrolytic solution and connected to an electric potential. An electric
current is passed through the raised contact and through an electrode
contained in the solution. This causes metal ions in the solution to
deposit onto the raised contact. Because the surface of the base metal
which forms the raised contact possesses an inherent roughness, the plated
layer begins to form with asperities or nodules and a rough or textured
surface forms on the contact. Additionally, process parameters are
controlled to enhance the roughness of the plated layer. For a raised
contact formed of a base metal such as aluminum, the plated layer can be a
material such as nickel, molybdenum, tungsten, platinum, iridium or gold,
which has a more positive electromotive potential than aluminum.
For forming a rough surface using an etching process, the raised contact is
formed and then etched using a wet or dry etch process. For a wet etching
process a wet etchant such as an acid can be used to enhance granular
boundaries and roughen the surface of the contact. Etching can also be
performed using a dry etch process such as plasma etching, ion milling, or
reactive ion etching.
In an illustrative embodiment, the raised contact is a microbump formed of
a base metal and attached to a polyimide substrate. The polyimide
substrate includes an electrically conductive trace in electrical
communication with the microbump. For forming an interconnect useful in
testing discrete die, the polyimide substrate is attached to a rigid
substrate formed of a material such as silicon, having a coefficient of
thermal expansion that closely matches a silicon die.
BRIEF DESCRIPTION OF THE DRAWINGS
FIGS. 1A-1E are schematic cross sectional drawings illustrating a process
for forming contacts in accordance with the method of the invention;
FIG. 2 is a schematic view of an electrolytic plating apparatus for
depositing a rough textured metal layer on a contact formed of a base
metal in accordance with the method of the invention;
FIG. 3 is an enlarged cross sectional view of a rough textured metal layer
plated onto the surface of a raised contact formed of a base metal in
accordance with the invention;
FIG. 4 is a schematic cross sectional view of a rough textured surface
formed on a contact using an etching process;
FIG. 5 is a cross sectional view of a portion of an interconnect having
contacts formed in accordance with the invention with a rough textured
surface; and
FIG. 6 is an enlarged cross sectional view of an alternate embodiment
raised contact formed in accordance with the invention with a rough
textured surface.
DETAILED DESCRIPTION OF THE INVENTION
The method of the invention is adapted to form a contact structure and
includes the steps of:
providing a compliant substrate;
attaching a metal layer to the compliant substrate;
patterning the metal layer to form conductive traces;
etching openings through the compliant substrate to the conductive traces;
forming raised contacts in the openings in electrical communication with
the conductive traces; and then
forming a rough textured surface on the raised contacts by electroplating
or etching.
Referring to FIGS. 1A-1E, the above identified method is illustrated in
schematic form. In FIG. 1A, a polyimide substrate 10 is provided. The
polyimide substrate 10 can be molded or fabricated out of a sheet of
polyimide material. Polyimide tapes are commercially available from DuPont
and are sold under the trademark Kapton.TM.. A layer of metal foil 12 is
attached to the polyimide substrate 10. The polyimide substrate 10 can be
cast onto the layer of foil 12 and then cured to form a unitary structure.
The polyimide substrate 10 forms a compliant electrically insulating
substrate.
Next, as shown in FIG. 1B, the metal foil 12 is patterned and etched to
form a pattern of conductive traces 14 on the polyimide substrate 10. The
metal foil is formed of a highly conductive material such as copper or
aluminum. Patterning and etching can be performed using a
photolithographic process in which a layer of photoresist is applied to
the metal foil 12, exposed, and then developed to form a mask for etching
using a wet etchant. One suitable wet etchant for a metal foil 12 formed
of copper is sulphuric acid. For aluminum, suitable wet etchants include
NaOH and KOH.
Next, as shown in FIG. 1C, a pattern of openings 16 is etched through the
polyimide substrate 10 to the conductive traces 14. Again, a photomask can
be formed and a wet etchant such as hydrazine used to etch the polyimide
substrate 10 with the pattern of openings 16.
Next, as shown in FIG. 1D, the openings 16 are filled with a metal plug 18
having a raised contact 20. The metal plugs 18 and contacts 20 can be
formed as a unitary structure using an electroplating process. Each raised
contact 20 is generally convex in shape.
Next, as shown in FIG. 1E, a rough textured surface 22 is formed on each
raised contact 20. The rough textured surface 22 can be formed by
depositing a rough metal layer on the raised contacts 22 using an
electroplating process. Alternately, the rough textured surface 22 can be
formed by etching the surfaces of the raised contacts 20 using a wet or
dry etching process.
Referring to FIGS. 2 and 3, an electrolytic plating process for forming the
rough textured surfaces 22 on the raised contacts 20 is shown. During the
electrolytic plating process the parameters of the process are controlled
to form a rough textured metal layer 22A (FIG. 3) with oxide penetrating
asperities 50A.
The electroplating apparatus 24 includes a tank 26 filled with an
electrolytic solution 28. The electrolytic solution 28 is a conductive
liquid that includes water, metal ions and a salt such as sodium chloride
(NaCl). Pairs of anodes 29, 30 are submerged in the electrolytic solution
28. Each anode 29, 30 is electrically connected to the positive electrode
of a power source 32. Depending on the metal being plated, the anodes 29,
30 are formed of a material that will supply positive ions to the
electrolytic solution 28. As an example for forming a layer of aluminum,
the anodes 29, 30 will also be formed of aluminum. A holder 34 is
submerged in the electrolytic solution and connected to the negative
electrode of the power source 32.
The polyimide substrate 10 is mounted to the holder 34 with the conductive
traces 14 and contacts 20A electrically connected to the negative
electrode of the power source 32. During the plating process, process
parameters (e.g., temperature, current density, composition of
electrolytic solution) are controlled to produce a rough plated layer. One
process parameter that can be controlled to produce a rough plated layer
is the chemical composition of the electrolytic solution. Specifically,
the presence or concentration of brighteners in the solution will affect
the grain structure and texture of the plated material. The term
brightener refers to any substance added to an electrolytic solution to
enhance the formation of a finer or denser grain structure in the plated
material. Such brighteners are usually adsorbed or diffused into the
plated layer. Brighteners, such as carbon, are routinely added to
electrolytic solutions during electrolytic plating to produce a smooth
plated surface.
In order to produce a rough textured surface, the brighteners are either
totally excluded from the electrolytic solution 28 or added in reduced
quantities from those normally used. By controlling the brighteners, the
textured metal layer 22A (FIG. 3) will form with a rough texture that
conforms to the surface of the base metal that forms the contacts 20A. Any
scratches, burrs or pores in the surface of the contacts 20A will be
magnified in the textured metal layer 22A.
FIG. 3 is a schematic cross sectional view illustrating the surfaces of the
raised contact 20A and the rough textured metal layer 22A magnified
several hundred times. The contact 20A is formed initially with a rough
surface 44A. The rough surface 44A of the contact 20A includes peaks and
valleys formed by scratches and burrs present on the surface of the base
metal. Some surface roughness occurs naturally during formation of the
contact 20A. As an example, during formation of contact using an
electroplating process (20, FIG. 1D) a imperfect surface is formed that
includes scratches and burrs. The contact 20A can also be further
roughened or scratched using an abrasive medium such as a wire brush,
emery wheel, or sandpaper prior to deposition of the rough metal layer
22A.
During the subsequent electroplating process, the textured metal layer 22A
is deposited on the surface 44A of the contact 20A and asperities 50A are
formed. The asperities are raised areas or nodules that form during
deposition of the textured metal layer 22A. These asperities 50A have a
random shape. Some of the asperities 50A will have a pointed or sharpened
peripheral configuration.
During the rough plating process, the asperities 50A form over the contour
of the rough surface 44A of the contact 20A and are magnified by the
electroplating process. This is a well known phenomena that occurs in
electroplating and can be alleviated by adding organic brighteners to the
electrolytic solution 28. In the present case this phenomena is encouraged
because a rough textured surface is desired. In addition, the voltages and
duration of the plating process are controlled to enhance the production
of a rough surface.
Such a rough textured metal layer 22A will have the ability to penetrate a
semiconductor die pad 48 (FIG. 5) and pierce any native oxide (not shown)
present on the pad 48. At the same time, the penetration depth into the
die pad 48 will be limited by the height "H" of the asperities 50A (FIG.
3). The height H is preferably on the order of 1000.ANG. to 10,000.ANG.,
with about 5000.ANG. being the average. This height H will also be
approximately the same as the thickness of the textured metal layer 22A.
The plating metal for forming the textured metal layer 22A is one that has
a more positive electromotive pote | | |
