The field of the invention is wafer processing technologies.
Production of solder bumps on a substrate (e.g., a silicon wafer) can be quite complex, and costly. One of the more costly time-consuming steps for placing solder bumps on a silicon wafer includes depositing multiple photoresist masking layers to ensure deposited material is placed, or is bonded with appropriate features of a semiconductor device. Time and money could be saved by eliminating the use of photoresist processing or masking steps when producing solder bumps.
A great deal of past effort has been directed to solder bump production, as evidenced by the following references:
The above references disclose various aspects of preparing or creating solder bumps that require a great number of complicated steps, including multiple photoresist processing or masking steps to form proper patterns on a substrate. Still, others have attempted to reduce a need for masking steps.
U.S. Pat. No. 5,492,235 to Crafts et al. titled “Process for Single Mask C4 Solder Bump Fabrication” (February 1996) describes a method for removing ball limiting metallurgy layers from the surface of a wafer in the presence of a lead-tin solder bump. Although Crafts discusses methods of improved C4 solder bump production by obviating a need to mask a solder bump while etching a ball limiting metallurgy, Crafts still requires one or more photoresist processing steps to create a support system around where a solder bump is to be created.
U.S. Pat. No. 6,570,251 to Akram et al. titled “Solder Bump Metallization Pad and Solder Bump Connections” (May 2003) also seeks to eliminate a masking step. Interestingly, as with Crafts, Akram also still requires one or more masking steps to create the solider bump. For example, a photoresist mask is applied to the surface of a passivation layer to form a mold for a solder bump.
Even with the progress made in solder bump production, photoresist or masks are still used. Additionally, known techniques result in non-uniform solder bumps, which can reduce efficiency of flip chip processing. What has yet to be appreciated is that highly uniform solid bumps can be created without the use of photoresist masks. Rather than using photoresist to support solder paste that is reflowed to form a solder bump, existing passivation layer material surrounding a bond pad can be used as a well where a solder bump can be formed, thereby eliminating the costly masking or photoresist processing steps required to build up a form for a solder bump. The well can be filled with a solder paste, and an a priori prepared solder ball can placed on the paste. For example, a solid prepared solder ball can be placed directly on the paste, or a solder ball can be applied to the paste as described in co-owned U.S. Pat. No. 7,007,833 titled “Forming Solder Balls on Substrates” (March 2006).
Unless the context dictates the contrary, all ranges set forth herein should be interpreted as being inclusive of their endpoints and open-ended ranges should be interpreted to include only commercially practical values. Similarly, all lists of values should be considered as inclusive of intermediate values unless the context indicates the contrary.
Thus, there is still a need for systems, methods, apparatus, configurations, or other solutions that allow for production of solder bumps with further reduced requirements for using photoresist masks.
The inventive subject matter provides apparatus, systems and methods in which solder bumps can be produced on a wafer. In one aspect, the inventive subject matter includes forming a solder bump on a substrate having a bond pad. In a preferred embodiment, the substrate comprises a silicon wafer, or other semiconductor device, with a well formed around the bond pad by an existing passivation layer, where the passivation material encroaches at or near to the edge of the bond pad. The passivation material forms well walls around the bond pad, where the well walls form an accessible window to an exposed surface of the bond pad. A workspace where the substrate is processed (e.g., a clean room, a building, a lab, a fab, etc.) is preferably configured to allow forming solder bumps on the substrate without the use of photoresist. An under bump metallization (UBM) layer comprising one or more metallization films can be also be deposited in the well. In some embodiments, a precursor film of the UBM layer can comprises Palladium, Platinum, or other suitable metals in contact with the bond pad. Additional films of the UBM layer can include an electroless plating film possibly of Nickel, or a non-oxidizing film possibly of Gold or Silver. A contact material, preferably solder paste, can be deposited into the well where the contact material is within electrical contact with the bond pad via one or more films of the UBM layer. In some embodiments, the UBM layer can act as the contact material. The contact material can be reflowed to form a non-bump solder tab in the well. An a priori prepared solder ball can be placed on the contact material (e.g., the solder tab) to form the solder bump.
Another aspect of the inventive subject matter includes forming solder bumps on a target substrate by reworking the target substrate. A target substrate having bond pads is provided where surfaces of the substrate are covered by a covering material that forms a well around exposed surfaces of the bond pads. Contact material is deposited into the wells, reflowed, and planarized to ensure the wells have uniform height. If necessary, the steps can be repeated to fill missed wells, fill gaps, or correct other deviations. Repeating the steps two, three, or more times ensures the production process has a high yield.
Various objects, features, aspects and advantages of the inventive subject matter will become more apparent from the following detailed description of preferred embodiments, along with the accompanying drawing figures in which like numerals represent like components.
In
One should note that in
In
Passivation layer 120 can deposited using known techniques and is preferably created as part of standard integrated circuit manufacturing processes when fabricating components on substrate 100. The disclosed techniques utilize existing passivation layers 120 as provided. It is also contemplated that passivation layer 120 can be made thicker to increase the depth of well 190 as desired by depositing additional passivation material.
Preferred passivation layers 120 have a thickness of roughly 0.5 to 50 micrometers, with a preferred thickness in the range from about 3 to about 5 micrometers. By contrast typical passivation layers have a thickness of 0.5 to 2.0 micrometers, and a via formed from photoresist typically requires a photoresist layer of less than 1 micrometer to prepare for solder bump formation. It is also contemplated that both thinner or thicker passivation layers could also be used.
Passivation layer 120 can comprise one or more various suitable materials. Preferred materials include a glass, a nitride, a polyimide, or other materials known or yet to be appreciated as useful for a passivation layer. Although passivation layer 120 is illustrated as a single layer, one should appreciate that passivation layer 120 could comprise multiple layers of deposited materials. For example, passivation layer 120 could include an initial glass or nitride passivation layer having a thickness of 0.5 to 2.0 micrometers. Then an additional polyimide passivation layer can be deposited to yield a passivation layer thickness of 5, 10, 20, or more micrometers.
In a preferred embodiment, the material used for creating passivation layer 120 forms a well wall around exposed surfaces of bond pad 110. The depth of well 190 can be commensurate with the thickness of passivation layer 120, or less. Preferred depths of well 190 can typically be from 0.5 to 50 micrometers, with a preferred depth of at least 3 micrometers. Deeper wells are also contemplated including wells having depths of 10, 20, 30 micrometers, or more. The dimensions of the exposed surface of bond pad 110 can be adjusted to fit a desired solder bump. One should note that well depth can affect a desired minimum exposed surface of bond pad 110 for a target solder bump. Typically, the exposed area of bond pad 110 is circular with typical diameters in the range from 25 to 1500 micrometers, with a preferred range from 50 to 1250 micrometers.
Once a target substrate 100 is provided, a work space is configured to operate on substrate 100 to form solder bumps. In a preferred embodiment, the work space is configured to allow solder bump formation without use of photoresist processing or masking steps. As will become evident below, depositing, masking, removing, or otherwise utilizing photoresist is simply not required. Preferably the surfaces of the layered materials discussed remain native, and substantially free from an effective amount of photoresist required for etching. Although a preferred embodiment lacks the use of photoresist, one should note that configuring a work space to use an ineffective or trivial amount of photoresist is considered to fall within the scope of the inventive subject matter. Configuring a work space is considered to include programming equipment, instructing individuals, or otherwise providing instructions to reduce or eliminate photoresist processing, or to reduce photoresist processing to the point of being trivial.
Preferably metallization film 132A is deposited by spraying a coating comprising the metallization precursor material into well 190, or by dipping substrate 100 into a bath having the film precursor material. In such embodiments, film 132A can be cured at a low temperature of less than 400 degrees Celsius, more preferably less than 150 degrees Celsius, and yet more preferably less than 90 degrees Celsius to force the precursor material to adhere to bond pad 110. A second film 134A of metallization layer 130A can be deposited by an electroless plating step after curing the precursor material. Remaining films (e.g., non-oxidizing film 136A) can be also deposited using known techniques. It is also contemplated that other methods can be employed to deposit various other films of metallization layer 130A including chemic vapor deposition, plasma-enhanced chemical vapor deposition, sputtering, or other techniques. One should note that the use of photoresist or masking is not required or necessary to properly place layer 130A. In fact, in some embodiments, layer 130A is can be deposited across substantial portions of the exposed native surfaces of substrate 100.
Although
In some embodiments, UBM layer 130A or 130B can function as contact material 140. For example, in embodiments where well 190 has a depth of 3 to 10 micrometers, it is thought that UBM layer 130A or 130B would be sufficient to contact to a prepared solder ball. In embodiments having deeper wells (e.g., greater than 10 micrometers), it is thought that solder paste serves well as contact material 140.
One should appreciate that in embodiments where solder paste is employed, the amount of solder paste deposited need not be strictly control. For example, less paste than required to fill well 190 could be deposited in well 190. When reflowed, the paste would form a solder tab where the surface of the tab at the top portion of well 190 could have a concaved depression. Excess paste on surfaces external to well 190 can then be removed by subsequent steps including through planarizing the surfaces of substrate 100 as discussed below.
In
Excesses of metallization layer 130A can be removed from external surfaces around well 190, preferably once reflow has been completed. This can be achieved by known wet etch techniques applied before or after placing of a solder ball. Again, no photoresist or masking of the surface is required.
In more preferred embodiments, substrate 100 can be planarized by grinding down exposed surfaces to remove UBM layer 130A. Planarization can occur before or after depositing contact material 140, or before or after reflowing of contact material 140. In such embodiments, passivation layer 120 operates as an etch stop to indicate when planarization should be stopped. Planarization can be conducted by simply grinding the surfaces of substrate 100 using finer and finer grit polish using establishing techniques. Planarizing the surfaces of substrate 100 can also be used to ensure that multiple wells 190 on substrate 100 have uniform depths.
In some embodiments, at least some of preceding steps illustrated up through
In
One or more of solder ball 150 can be placed directly on contact material 140 before reflow, or directly on solder tab 145 after contact material 140 has been reflowed. One acceptable method of placing solder ball 150 includes placing solid-preformed solder balls using a solder ball drop process. Another acceptable method includes placing solder ball 150 in a liquid or molten form on contact material 140 or solder tab 145. In either case, solder ball 150 can be bonded to the underlying contact material 140 by heating solder ball 150 and contact material 140, if necessary, in a manner where the ball forms an integral bond with the material. When solder ball 150 is in a molten form, its own heat can cause it to bond to solder tab 145.
One should keep in mind that the disclosed processes for attaching solder ball 150 to solder tab 145 can be applied across a plurality of bond pads 110 and their associated wells 190. In a preferred embodiment, a plurality of solder balls 150 is placed substantially at the same time. This can be achieved by adapting techniques developed by Spheretek LLC Division of MVM Technologies, Inc., of Sunnyvale Calif., as described in U.S. Pat. No. 7,007,833 titled “Forming Solder Balls on Substrates” (March 2006). A solder ball template can be created having solder balls held in cells of the template, where the balls can be arranged in a pattern that mirrors that of the wells 190 on substrate 100. In a preferred embodiment, the solder ball template comprises cells that hold liquid or molten solder, where the arrangement of the template cells mirror the arrangement of wells 190 on target substrate 100. The solder ball template can then be juxtaposed with substrate 100 and wells 190 in a manner where one or more of the liquid solder balls 150 in their cells contact solder tabs 145 in wells 190. The heat of the molten solder balls causes the solder balls 150 to transfer to their corresponding wells 190 due to the ball's interference fit in the cells, and to form a solder bump. One should note that no photoresist is used, and that no masking of the substrate is required. It should be appreciated that preparing solder balls 150 separately from processing substrate 100 allows for a parallel work flow that decreases processing time in solder ball formation.
Preferred solder balls 150 are produced to have a uniform sphereicity to within a tolerance down to ±10 micrometers, or more preferably down to ±5 micrometers. Additionally, preferred solder balls 150 can have diameters in the range from 25 to 1500 micrometers, or more preferably from 50 to 1250 micrometers. Preferably solder balls 150 comprise Pb, Pb/Sn, or other metallurgies. Acceptable solder balls can be obtained from MVM Technologies Inc., of San Clemente, Calif. One should note that the solder balls 150 placed on substrate 100 can also be of a heterogeneous sizes and dimensions. In fact, each well in a solder ball template could be different from other wells of the template.
At step 810, a substrate, preferably a wafer, is provided having one or more bond pads. Preferably the substrate is the result of a standard IC manufacturing process, and has an existing passivation layer. In some embodiments, the bond pads are arranged on the wafer in regular repeating patterns, and in other embodiments the bond pads are arranged irregularly. The substrate preferably has a passivation layer covering surfaces of the substrate and that also forms wells around bond pads disposed on the substrate, where the bond pads retain exposed surfaces at the bottom of the well. In some embodiments, additional passivation layer material is deposited to ensure wells have desired depths.
At step 815, a work space used for forming solder bumps on the substrate is prepared by configuring the work space to allow bump formation without the use of photoresist processing, or even masking the substrate. Configuring the work space preferably includes providing instructions to one or more substrate processing equipment. Instructions can be provided by programming equipment, programming control systems, or other known techniques. The work space can include a processing line, a lab, a fab, a building, or other area through which a substrate can be processed. Instructions can include instructing the equipment or individuals to deposit less than an effective amount of photoresist for etching on native surfaces of the substrate or its layers. Instructions can also include instructing equipment or individuals to leave surfaces free from an effective amount of photoresist.
At step 820, an UBM layer can be deposited on top of the passivation layer, or in the wells of the bond pads where the UBM layer covers exposed surfaces of the bond pads. In a preferred embodiment, the UMB layer comprises at least one metallization film. The layer can comprise one or more films including an adhesion film of a precursor material, a film of an electroless plating material, or a film of a capping material. Preferred precursor films comprise a Pd or a Pt precursor material that contacts the bond pad directly. The UMB layer provides electrical contact between the contact pad and other materials deposited within the well. At step 823, a precursor film can be deposited via spraying a precursor material into at least the wells of the bond pads, or at step 825 the substrate can be dipped into a bath having the precursor material in solvent form. In preferred embodiments, the solvent only wets material of the bond pad and does not wet or adhere to the passivation layer. At step 827 the precursor film can be cured, preferably at a low temperature of less than about 150 degrees Celsius, or more preferably at less than about 90 degrees Celsius.
At step 830 a contact material is deposited in the wells. In some embodiments, a UBM layer functions as the contact material. In other embodiments, a solder paste is used as a contact material. For example, solder paste can be placed within the wells, and fills the wells substantially to the top of the well walls. The contact material can be deposited using known techniques including spreading the contact material via squeegee, or using PCB stenciling techniques. Contact material external to the well can be easily removed after reflowing by washing the substrate, or through planarization (see also step 855).
Preferred solder paste has small particle size relative to the dimensions of the target wells. Small sized particles reduce a risk of having voids in the well, or having non-intimate contact with the UBM layer. Preferred solder paste has particles of less than about 25 micrometers in size, more preferably less than about 15 micrometers, and yet more preferably less than 12 micrometers.
As step 840 the contact material is preferably reflowed to form a solder tab, preferably a non-bump solder tab. In a preferred embodiment, the solder tabs comprises an approximately level surface across a top portion of a bond pad well, or even a concave surface across the top of the well in a depression. One should appreciate that the disclosed techniques have a high degree of tolerance with respect to the amount of contact material deposited into the wells. In preferred embodiments, as shown, step 840 is performed before attaching a solder ball. In other embodiments, step 840 can be performed after attaching a solder ball. In some embodiments, a precursor film material of the under bump metallization layer can remain substantially intact. Such an approach ensures that a solid, strong, electrical contact is made between the solder tab and the bond pad.
At step 850, preferably after step 840 and if necessary, excess UMB layer material can be removed from surfaces external to bond pad wells. In some embodiments, the excess material can be removed by wet etching. In other embodiments, at step 855, the excess material can be removed by planarizing the surfaces of the target substrate as discussed above. The surfaces can be planarized by polishing the surfaces using finer and finer grit abrasives, preferably until the passivation layer is reached. As previously discussed, planarization removes excess material as well as ensures that multiple wells have uniform heights.
At optional step 857, one or more of the above steps can be repeated to ensure all wells are prepared properly. Repeating the steps can increase the yield of the overall process. For example, after reflowing, if some wells are revealed to have voids, gaps, or lack contact material, then additional contact material can be deposited to fill gaps, reflowed again, and planarized again. It is contemplated that repeating one or more of the steps two, three, or more times is sufficient to results in yield of greater than 99%. In fact, it is also contemplated that repeating the steps is of sufficient value that repeating the steps can be made as a standard part of the process.
At step 860, an a prior prepared solder ball can be placed on the contact material. The solder ball maintains electrical contact with the underlying bond pad via the contact material (e.g., a solder tab, or UBM layer). A prepared solder ball, either in liquid or solid form, preferably contacts the surface of the contact material, even if the surface of the contact material is concaved and has a depression in to the well. The curve the ball simply extends into the depression of the concaved surface until contact is achieved.
One method for placing a prepared solder ball is described at step 865. Solder balls can be placed in the wells of a target substrate by utilizing a template having cells that hold the solder balls in liquid or molten form. The template's solder ball cells are preferably arranged in a pattern that mirrors the patterns of the wells on the target substrate. The template can be moved into a juxtaposed position with the target substrate, where the solder balls contact the contact material in the wells of the target substrate. As discussed in U.S. Pat. No. 7,007,833, the molten solder balls extend slightly from their cells due to an interference fit, and can wet the contact material of the wells even if the wells have a depressed concave surface.
At step 866, it is also contemplated that solder balls in the form of a solder paste can be placed on the contact material. For example, using the template technique described above with respect to step 865, the cells of the template can be filled with solder paste. When the template is placed in a juxtaposed position with a target substrate, the assembly can be heated to reflow the paste in the cells of the template. The cell's reflowed solder balls contacts the contact material in the wells of the target template and bonds with the contact material.
Another acceptable method for placing a prepared solder ball is shown as step 867. At step 867, solid solder balls are placed using any acceptable method including solder ball drop process. Other techniques for placing solid balls can also be used.
At step 870, solder balls contact with the solder tab in the wells, and bonds to the solder tab. In embodiments using molten solder balls, the solder balls bond via the temperature of the molten solder material. Alternatively, the target substrate having solid solder balls can be heated, if necessary, to reflow the contact material, possibly a second, third, forth, or more times, to bond the solder balls to the wells. The result is that the wells have solder bumps that are tightly coupled to, and in strong electrical contact with the bond pads of the wells.
It is also contemplated that once solder balls are formed on the target substrate, the ball array could be optionally planarized to ensure that all balls have uniform heights, or desired topologies. Once planarized, the balls can be reflowed again, if necessary to restore the balls to sphere shape.
At step 880, it should be noted that method 800 is conducted while lacking a use of a photoresist processing or masking of the substrate.
One should appreciate there are numerous advantages due to the disclosed techniques including:
It should be apparent to those skilled in the art that many more modifications besides those already described are possible without departing from the inventive concepts herein. The inventive subject matter, therefore, is not to be restricted except in the spirit of the appended claims. Moreover, in interpreting both the specification and the claims, all terms should be interpreted in the broadest possible manner consistent with the context. In particular, the terms “comprises” and “comprising” should be interpreted as referring to elements, components, or steps in a non-exclusive manner, indicating that the referenced elements, components, or steps may be present, or utilized, or combined with other elements, components, or steps that are not expressly referenced. Where the specification claims refers to at least one of something selected from the group consisting of A, B, C . . . and N, the text should be interpreted as requiring only one element from the group, not A plus N, or B plus N, etc.
This application claims the benefit of priority to U.S. provisional application having Ser. No. 61/056,562 filed on May 28, 2008. This and all other extrinsic materials discussed herein are incorporated by reference in their entirety. Where a definition or use of a term in an incorporated reference is inconsistent or contrary to the definition of that term provided herein, the definition of that term provided herein applies and the definition of that term in the reference does not apply.
Number | Date | Country | |
---|---|---|---|
61056562 | May 2008 | US |