US20060250139A1 - Bond pad structure comprising multiple bond pads with metal overlap - Google Patents
Bond pad structure comprising multiple bond pads with metal overlap Download PDFInfo
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- US20060250139A1 US20060250139A1 US11/485,002 US48500206A US2006250139A1 US 20060250139 A1 US20060250139 A1 US 20060250139A1 US 48500206 A US48500206 A US 48500206A US 2006250139 A1 US2006250139 A1 US 2006250139A1
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- die
- bond pad
- bond
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Definitions
- the present invention relates generally to fabrication of integrated circuit devices and, more particularly, to a bond pad construction and methods for forming and using the bond pad structure.
- Integrated circuits are typically tested before they are packaged to determine if they have any failing circuitry.
- a series of bond pads on the die referred to as test bond pads, are used in testing a die.
- one of the first steps in testing a die is to initiate a test mode in the die by applying control signals to the test bond pads. After the test is completed, a signal is sent to the test bond pads to short them out and disable them.
- the test bond pad is not disabled but is converted to an operational mode.
- leakage problems can result.
- the separation of the test mode from the operational mode would help solve this problem.
- the separation would also protect operational devices from high voltages during testing. It would be desirable to provide such a structure in the form of two separate bond pads, one bond pad functional in a test mode and, when connected to the other bond pad, both functioning as a single pad in a operational mode. In fabricating such a bond pad structure, consideration must be given to the structuring of the two bond pads in conjunction with each other.
- the present invention encompasses methods of forming bond pad structures in a semiconductor fabrication, bond pad structures formed from such methods, integrated circuit die incorporating the bond pad structure, and methods of utilizing the bond pad structures in testing and operating a semiconductor device.
- the invention provides a bond pad structure in a semiconductor device, the bond pad structure comprising two bond pads within a bond pad opening.
- each of the bond pads comprise stacked metal layers of an upper metal layer and at least one lower metal layer.
- the bond pads are structured such that the lower metal layer of one of the bond pads extends beneath the upper metal layer of the other of the bond pads.
- the bond pads can comprise multiple lower metal layers with one or more layers of one bond pad extending underneath the upper metal layer of the other bond pad.
- the metal layers are in essence, interwoven or staggered to protect the underlying substrate.
- the extension of a lower metal layer beneath an upper metal layer functions as an etch block to prevent etching of a dielectric (insulating) layer between the first and second bond pads down to the underlying substrate, which can occur during etching of the passivation layer to form the bond pad opening.
- the bond pad structure comprises a first metal layer deposited onto a substrate and patterned by dry etching to form two lower metal layers with a space thereinbetween; a dielectric layer deposited over the lower metal layers and the exposed substrate within the space and etched to form openings to each of the two lower metal layers; a second metal layer deposited over the dielectric layer and into the openings of the dielectric layer and etched to form two upper metal layers overlying the two lower metal layers, resulting in the two bond pads, each comprising stacked upper and lower metal layers.
- the lower metal layers are etched such that a lower metal layer of one of the bond pads extends underneath the upper metal layer of the other of the bond pads to form an interwoven layered structure.
- a passivation layer can be formed over the upper metal layers and etched to form a bond pad opening to expose the two bond pads.
- the staggering of a lower metal layer beneath an upper metal layer forms an etch block during etching of a passivation layer to protect the underlying substrate.
- the bond pads can be interconnected by a conductive material.
- the bond pads can function to supply data, retrieve data, test a device, and supply various voltages for testing or programming.
- An exemplary bond pad structure comprises a test mode bond pad not connected to and separate from an operational mode bond pad. When the test sequence is complete, the test mode of the test mode bond pad is disabled. The two pads are then connected during wire bonding, and the resulting joined bond pads function in an operational mode.
- the bond pads can be interconnected, for example, by a solder material that is used in the connection of a wire bond to the surface of the bond pad structure.
- the lower metal layer of the first bond pad can extend underneath the upper metal layer of the second bond pad (e.g., test mode bond pad).
- the lower metal layer of the second bond pad e.g., a test mode bond pad
- each of the bond pads can comprise a plurality of lower metal layers whereby at least one of the lower metal layers of one of the bond pads extends underneath the upper metal layer of the other of the bond pads.
- the invention encompasses an integrated circuit die comprising the bond pad structure of the invention.
- the invention provides a method of forming a bond pad structure as described herein, comprising a first and second bond pad.
- the method of the invention comprises the steps of: depositing a first metal layer onto a substrate; etching the first metal layer to form first and second lower metal layers having a space thereinbetween; depositing a dielectric layer over the first and second lower metal layers and into said space thereinbetween; etching the dielectric layer to form openings to each of the first and second lower metal layers; depositing a second metal layer over the dielectric layer and into the openings of the dielectric layer; and etching the second metal layer to form first and second upper metal layers having a space thereinbetween.
- the resulting bond pad structure comprises a first bond pad comprising the first upper metal layer overlying the first lower metal, and a second bond pad comprising the second upper metal layer overlying the second lower metal layer.
- the method can further comprise forming a passivation layer over the first and second upper metal layers and into the space thereinbetween; and etching the passivation layer to form an opening to expose the first and second upper metal layers of the bond pads.
- the lower metal layer of one bond pad extends underneath the upper layer of the other bond pad and functions to block the etching of a dielectric layer that is deposited over the lower metal layers and the underlying substrate, and to protect the substrate from damage, for example, during etching of the passivation layer to form the bond pad opening.
- the method can further comprise the steps of connecting a bonding wire to one of the bond pads, and interconnecting the bond pads with a conductive material such as a solder material used in the attachment of the bonding wire.
- a method of testing and/or operating an integrated circuit using an integrated circuit die comprising a bond pad structure as described herein comprises a first bond pad which is a test mode bond pad that receives and responds to a test mode signal and, after the test sequence is complete and the first and a second bond pad of the bond pad structure are interconnected with a conductive material, the first and second bond pads function as a single unit to receive and respond to any signal.
- FIGS. 1A-1D are diagrammatic cross-sectional views of a semiconductor wafer at subsequent and sequential processing steps, showing fabrication of a bond pad structure.
- FIGS. 2A-2I are diagrammatic cross-sectional views of a semiconductor wafer at subsequent and sequential processing steps, showing fabrication of a bond pad structure according to an embodiment of a method of the invention.
- the terms “semiconductive wafer fragment” or “wafer fragment” or “wafer” will be understood to mean any construction comprising semiconductor material, including but not limited to bulk semiconductive materials such as a semiconductor wafer (either alone or in assemblies comprising other materials thereon), and semiconductive material layers (either alone or in assemblies comprising other materials).
- substrate refers to any supporting structure including, but not limited to, the semiconductive wafer fragments or wafers described above.
- FIG. 1A The fabrication of such a bond pad structure is depicted in FIG. 1A .
- the illustration illustrates a design flaw in the bond pad structure that is overcome by the present invention, as will be described and illustrated with reference to FIGS. 2A-2I .
- a semiconductor wafer fragment 10 is shown as comprising a substrate 12 , which can comprise a semiconductor wafer substrate or the wafer along with various process layers formed thereon, including one or more semiconductor layers or other formations, and active or operable portions of semiconductor devices.
- the bond pad structure 40 comprises a first bond pad 28 and a second bond pad 30 , each formed from two overlying stacks of metal, although additional layers of metal can be utilized.
- a first metal layer 14 has been deposited onto the substrate 12 and patterned by dry etching resulting in a lower metal layer 16 a of the first bond pad 28 , and a lower metal layer 16 b of the second bond pad 30 , having a space 18 thereinbetween.
- a dielectric layer 20 such as SiO 2 has been deposited over the lower metal layers 16 a , 16 b and into the space 18 to electrically isolate the two lower metal layers 16 a , 16 b from each other, and to isolate the lower metal layers 16 a , 16 b from the upper metal layers 26 a , 26 b of the second metal layer 24 .
- the dielectric layer 20 has been etched to provide vias or openings 22 to allow electrical connection between the first and second metal layers 14 , 24 .
- a second metal layer 24 has been deposited over the dielectric layer 20 and into the openings 22 a , 22 b.
- the second metal layer 24 has been patterned by dry etching to form an upper metal layer 26 a of the first bond pad 28 and an upper metal layer 26 b of the second bond pad 30 , which are separated by a space 32 .
- a passivation layer 34 has been put down on the wafer surface to seal the device structures from contamination and moisture, and as a scratch protection layer.
- an opening 36 has been etched into the passivation layer 34 to expose the set of bond pads 28 , 30 , which form the bond pad structure 40 .
- a disadvantage of the construction shown in FIG. 1D is that, due to the alignment of the upper and lower metal layers of the bond pads 28 , 30 , the dielectric material 20 , between the two bond pads 28 , 30 can be etched out during the passivation etch resulting in weak points or an opening 38 down to the substrate 12 . This exposure of the substrate 12 can result in a short on the die and device failure. This problem is overcome by the present invention.
- FIGS. 2A-2I An embodiment of the method of the present invention is illustrated with reference to FIGS. 2A-2I , in forming a set of bond pads similar to that described with reference to FIGS. 1A-1C .
- a semiconductor wafer fragment 10 ′ is shown at a preliminary processing step.
- the wafer fragment 10 ′ is shown as comprising a substrate 12 ′, similar to wafer fragment 10 with various process layers formed thereon.
- a first metal layer 14 ′ has been deposited onto the substrate 12 ′.
- the first metal layer 14 ′ is formed from aluminum, aluminum alloys, titanium tungsten (Ti:W) alloys, platinum, copper, refractory metal silicides or other metals or metal alloys.
- the first metal layer 14 ′ can be deposited, for example, by CVD or other method known and used in the art.
- the first metal layer 14 ′ is in electrical contact with active areas in the substrate 12 ′.
- Each pad 28 ′, 30 ′ is connected to its own set of devices, which are combined after bonding of the pads 28 ′, 30 ′.
- the first metal layer 14 ′ is masked and patterned by dry etching to form a lower metal layer 16 a ′ of the first bond pad 28 ′, and a lower metal layer 16 b ′ of the second bond pad 30 ′, having a space 18 ′ thereinbetween, as illustrated in FIG. 2B .
- the patterning of the first metal layer 14 ′ is such that a lower metal layer of one of the bond pads extends beneath the upper metal layer of the other bond pad.
- the first metal layer 14 ′ has been patterned and etched such that the lower metal layer 16 b ′ of the second bond pad 30 ′ will extend underneath the subsequently formed upper metal layer 26 a ′ of the first bond pad 28 ′.
- a dielectric layer 20 ′ such as SiO 2 is then deposited over the first metal layer 14 ′ and into the space 18 ′ to electrically isolate the two lower metal layers 16 a ′, 16 b ′, and to isolate the first metal layer 14 ′ from the subsequently deposited second metal layer 24 ′.
- the dielectric layer 20 ′ is selectively etched to provide openings or vias 22 a ′, 22 b ′ to expose each of the first and second metal portions 16 a ′, 16 b ′ of the first metal layer 14 ′.
- the openings 22 a ′, 22 b ′ can be formed by conventional masking and silicon etching techniques including, for example, photolithographic and plasma etching processes.
- the etched opening 22 b ′ to the lower metal layer 16 b ′ is depicted as being larger in diameter than the opening 22 b ′.
- the metal portion that is subsequently deposited into the opening 22 b ′ is wider in diameter than the metal portion within the opening 22 a ′.
- the etched openings 22 a ′, 22 b ′ can be any proportion to each other to suit the particular need, including equal in diameter.
- a second metal layer 24 ′ is then deposited into the openings 22 a ′, 22 b ′ and as a layer over the insulative dielectric layer 20 ′.
- the second metal layer 24 ′ can comprise the same or different metal as the first metal layer 14 ′, being aluminum in the illustrated example.
- the second metal layer 24 ′ is thicker than the first metal layer 14 ′ in order to reduce resistance in the second metal layer 24 ′.
- the second metal layer 24 ′ is then patterned and dry etched to form an upper metal layer 26 a ′ of the first bond pad 28 ′ and an upper metal layer 26 b ′ of the second bond pad 30 ′, which are separated by a space 32 ′ thereinbetween.
- the upper metal layers 26 a ′, 26 b ′ of the first and second bond pads 28 ′, 30 ′ are depicted as generally comprising about the same relative area, but can be any proportion to each as desired.
- the lower metal layer 16 b ′ of the second bond pad 30 ′ extends underneath the upper metal layer 26 a ′ of the first bond pad 28 ′ to provide an interwoven or staggered layered structure.
- the lower metal layer 16 a ′ of the first bond pad 28 ′ can be patterned and etched to extend beneath the upper metal layer 26 b ′ of the second bond pad 30 ′.
- the bond pads 28 ′, 30 ′ can also comprise additional stacked metal layers (e.g., lower metal layers 16 a 1 ′, 16 a 2 ′, 16 b 1 ′, 16 b 2 ′) that can be formed to provide a staggered construction, as illustrated in FIGS. 2 F(b) and 2 F(c).
- a protective passivation layer 34 ′ is then formed over the semiconductor wafer 10 ′.
- the passivation layer 34 ′ such as CVD PSG or plasma-enhanced CVD silicon nitride, is put down on the wafer surface to seal the device structures from contamination and moisture, and as a scratch protection layer.
- the passivation layer 34 ′ can also be fabricated, for example, from polyimide, acrylate, epoxy potting compound, acrylic, silicone, polyurethane or other resin, among other protective coating materials, using conventional methods in the art including spin coating, spraying, flow coating, brush coating, among other application techniques.
- the passivation layer 34 ′ is then masked and etched by conventional photolithography methods to form a bond pad opening 36 ′ to expose the upper metal layers 26 a ′, 26 b ′ of each of the first bond pad 28 ′ and the second bond pad 30 ′.
- the exposed bond pads 28 ′, 30 ′ are typically about 100 by 100 ⁇ m in size and separated by a space 32 ′, for example, of about 0.5 ⁇ m, or other minimum space or distance allowable for the metal that is utilized.
- etching of the passivation layer 34 ′ also results in an opening 36 ′ being formed through the dielectric layer 20 ′ between the first and second bond pads 28 ′, 30 ′.
- the offsetting of the lower metal layer 16 b ′ of the second bond pad 30 ′ to extend underneath the upper metal layer 26 a ′ of the first bond pad 28 ′ serves as an etch block during the passivation layer etch, thereby preventing the insulation layer 20 ′ between the two bond pads from being etched down to the substrate 12 ′.
- a bonding wire 42 ′ can then be connected (bonded) to the metal of each of the bond pads and then to the chip package (not shown). In this way, electrical connections are established from the combined pads to an external electrical connection (i.e., the package leads) or to establish an internal-only operational function.
- a conductive material 44 ′ such as a solder material attaching the wire 42 ′ to the bond pads can be flowed across the surface of the first and second bond pads 28 ′, 30 ′ and into the space 38 ′ to connect the two bond pads.
- the bonding wire 42 ′ is not required in all applications, in which case a conductive material (e.g., solder) can be applied to join the pads together.
- the bond pad structure 40 ′ is useful in numerous applications including enable operations, supplying and/or retrieving data, powering, grounding, testing circuitry, among other functions. For example, methods of testing an integrated circuit using a test enable bond pad are generally described, for example, in U.S. Pat. Nos. 6,240,535 and 5,796,746 (Farnworth et al., to Micron Technology, Inc.).
- the integrated circuit (IC) module (not shown) generally includes a terminal receiving a test mode signal, and an IC die having a function circuit and a bond pad.
- a switching device such as a fuse that is blown or a transistor that is deactivated once testing is complete, is connected with the test mode bond pad between the terminal and the function circuit to conduct the test mode signal to the function circuit.
- the test mode bond pad is connected to the function circuit and enables a test mode in an I.C. die.
- An impedance device such as a resistor or anti-fuse, connected between the function circuit and an operational mode signal, supports a difference in voltages between the test mode signal at the function circuit and the operation mode signal. Briefly, a supply voltage is applied to the test mode bond pad, and the function circuit responds to the test mode signal by initiating a test mode in the die to test the circuitry thereon.
- a voltage is applied to disable the test mode, and the impedance device then conducts the operation mode signal to the function circuit.
- the function circuit responds to the operational mode signal by entering an operational mode in the die in which the die operates in accordance with its intended normal function.
- the first bond pad 28 ′ can comprise an operational mode bond pad that functions in an operational mode.
- the second bond pad 30 ′ can comprise a test mode bond pad that functions initially in a test mode for testing of circuitry and subsequently, upon completion of the circuit testing and its connection to the first bond pad 28 ′, in an operational mode as a single unit with the first bond pad 28 ′.
- the connection between the first and second bond pads 28 ′, 30 ′ can be performed by applying a conductive material 44 ′ (e.g., solder) over at least a portion of each of the bond pads 28 ′, 30 ′ to form an extension between the two pads.
- first bond pad can be a test mode bond pad and the second bond pad can be an operational mode bond pad.
- Such a structure is useful for testing an integrated circuit, and functioning in an operational mode once the individual bond pads are connected.
- the separation of the first and the second bond pads 28 ′, 30 ′ avoids leakage problems that can be caused by high voltage that is applied when the fuse or antifuse is blown at the end of a test operation.
Abstract
A bond pad structure comprising two bond pads, methods of forming the bond pad structure, an integrated circuit die incorporating the bond pad structure, and methods of using the bond pad structure are provided. Each of the bond pads comprise stacked metal layers, at least one lower metal layer and an upper metal layer. When the two pads are connected by a conductive material, they function as a single pad. The lower metal layer of one of the bond pads forms an extension that extends beneath the upper metal layer of the other of the bond pad. The lower metal extension functions to block the etching of a dielectric layer that is put down over the upper metal layers and the underlying substrate, for example, during a passivation etch to form the bond pad opening, to protect the substrate from damage.
Description
- The present application is a division of application Ser. No. 10/389,455, filed on Mar. 14, 2003, which is a division of application Ser. No. 09/927,675, filed on Aug. 10, 2001, now U.S. Pat. No. 7,064,447.
- The present invention relates generally to fabrication of integrated circuit devices and, more particularly, to a bond pad construction and methods for forming and using the bond pad structure.
- Integrated circuits (IC) are typically tested before they are packaged to determine if they have any failing circuitry. A series of bond pads on the die, referred to as test bond pads, are used in testing a die. In general, one of the first steps in testing a die is to initiate a test mode in the die by applying control signals to the test bond pads. After the test is completed, a signal is sent to the test bond pads to short them out and disable them.
- In some constructions, the test bond pad is not disabled but is converted to an operational mode. However, in shorting a fuse or using a high voltage to disable a transistor to terminate the test mode, leakage problems can result. The separation of the test mode from the operational mode would help solve this problem. The separation would also protect operational devices from high voltages during testing. It would be desirable to provide such a structure in the form of two separate bond pads, one bond pad functional in a test mode and, when connected to the other bond pad, both functioning as a single pad in a operational mode. In fabricating such a bond pad structure, consideration must be given to the structuring of the two bond pads in conjunction with each other.
- The present invention encompasses methods of forming bond pad structures in a semiconductor fabrication, bond pad structures formed from such methods, integrated circuit die incorporating the bond pad structure, and methods of utilizing the bond pad structures in testing and operating a semiconductor device.
- In one aspect, the invention provides a bond pad structure in a semiconductor device, the bond pad structure comprising two bond pads within a bond pad opening. In an embodiment of the bond pad structure, each of the bond pads comprise stacked metal layers of an upper metal layer and at least one lower metal layer. The bond pads are structured such that the lower metal layer of one of the bond pads extends beneath the upper metal layer of the other of the bond pads. The bond pads can comprise multiple lower metal layers with one or more layers of one bond pad extending underneath the upper metal layer of the other bond pad. The metal layers are in essence, interwoven or staggered to protect the underlying substrate. The extension of a lower metal layer beneath an upper metal layer functions as an etch block to prevent etching of a dielectric (insulating) layer between the first and second bond pads down to the underlying substrate, which can occur during etching of the passivation layer to form the bond pad opening.
- The bond pad structure comprises a first metal layer deposited onto a substrate and patterned by dry etching to form two lower metal layers with a space thereinbetween; a dielectric layer deposited over the lower metal layers and the exposed substrate within the space and etched to form openings to each of the two lower metal layers; a second metal layer deposited over the dielectric layer and into the openings of the dielectric layer and etched to form two upper metal layers overlying the two lower metal layers, resulting in the two bond pads, each comprising stacked upper and lower metal layers. According to the invention, the lower metal layers are etched such that a lower metal layer of one of the bond pads extends underneath the upper metal layer of the other of the bond pads to form an interwoven layered structure. A passivation layer can be formed over the upper metal layers and etched to form a bond pad opening to expose the two bond pads. The staggering of a lower metal layer beneath an upper metal layer forms an etch block during etching of a passivation layer to protect the underlying substrate. The bond pads can be interconnected by a conductive material.
- The bond pads can function to supply data, retrieve data, test a device, and supply various voltages for testing or programming. An exemplary bond pad structure comprises a test mode bond pad not connected to and separate from an operational mode bond pad. When the test sequence is complete, the test mode of the test mode bond pad is disabled. The two pads are then connected during wire bonding, and the resulting joined bond pads function in an operational mode. The bond pads can be interconnected, for example, by a solder material that is used in the connection of a wire bond to the surface of the bond pad structure.
- In an embodiment of the bond pad structure, the lower metal layer of the first bond pad (e.g., operational mode bond pad) can extend underneath the upper metal layer of the second bond pad (e.g., test mode bond pad). In another embodiment of the bond pad structure, the lower metal layer of the second bond pad (e.g., a test mode bond pad) can extend underneath the upper metal layer of the first bond pad (e.g., an operational mode bond pad). In yet another embodiment, each of the bond pads can comprise a plurality of lower metal layers whereby at least one of the lower metal layers of one of the bond pads extends underneath the upper metal layer of the other of the bond pads.
- In another aspect, the invention encompasses an integrated circuit die comprising the bond pad structure of the invention.
- In yet another aspect, the invention provides a method of forming a bond pad structure as described herein, comprising a first and second bond pad. In one embodiment, the method of the invention comprises the steps of: depositing a first metal layer onto a substrate; etching the first metal layer to form first and second lower metal layers having a space thereinbetween; depositing a dielectric layer over the first and second lower metal layers and into said space thereinbetween; etching the dielectric layer to form openings to each of the first and second lower metal layers; depositing a second metal layer over the dielectric layer and into the openings of the dielectric layer; and etching the second metal layer to form first and second upper metal layers having a space thereinbetween. The resulting bond pad structure comprises a first bond pad comprising the first upper metal layer overlying the first lower metal, and a second bond pad comprising the second upper metal layer overlying the second lower metal layer.
- The method can further comprise forming a passivation layer over the first and second upper metal layers and into the space thereinbetween; and etching the passivation layer to form an opening to expose the first and second upper metal layers of the bond pads. The lower metal layer of one bond pad extends underneath the upper layer of the other bond pad and functions to block the etching of a dielectric layer that is deposited over the lower metal layers and the underlying substrate, and to protect the substrate from damage, for example, during etching of the passivation layer to form the bond pad opening. The method can further comprise the steps of connecting a bonding wire to one of the bond pads, and interconnecting the bond pads with a conductive material such as a solder material used in the attachment of the bonding wire.
- In yet another aspect of the invention, a method of testing and/or operating an integrated circuit using an integrated circuit die comprising a bond pad structure as described herein, is provided. An embodiment of a bond pad structure of an integrated circuit die for use in testing and operating circuitry, comprises a first bond pad which is a test mode bond pad that receives and responds to a test mode signal and, after the test sequence is complete and the first and a second bond pad of the bond pad structure are interconnected with a conductive material, the first and second bond pads function as a single unit to receive and respond to any signal.
- Preferred embodiments of the invention are described below with reference to the following accompanying drawings, which are for illustrative purposes only. Throughout the following views, the reference numerals will be used in the drawings, and the same reference numerals will be used throughout the several views and in the description to indicate same or like parts.
-
FIGS. 1A-1D are diagrammatic cross-sectional views of a semiconductor wafer at subsequent and sequential processing steps, showing fabrication of a bond pad structure. -
FIGS. 2A-2I are diagrammatic cross-sectional views of a semiconductor wafer at subsequent and sequential processing steps, showing fabrication of a bond pad structure according to an embodiment of a method of the invention. - The invention will be described generally with reference to the drawings for the purpose of illustrating the present preferred embodiments only and not for purposes of limiting the same. The figures illustrate processing steps for use in the fabrication of semiconductor devices in accordance with the present invention. It should be readily apparent that the processing steps are only a portion of the entire fabrication process.
- In the current application, the terms “semiconductive wafer fragment” or “wafer fragment” or “wafer” will be understood to mean any construction comprising semiconductor material, including but not limited to bulk semiconductive materials such as a semiconductor wafer (either alone or in assemblies comprising other materials thereon), and semiconductive material layers (either alone or in assemblies comprising other materials). The term “substrate” refers to any supporting structure including, but not limited to, the semiconductive wafer fragments or wafers described above.
- It is desirable to provide a set of bond pads comprising a first bond pad and a second adjacent bond pad that can function independently, or as a single unit upon being interconnected by a conductive material. The fabrication of such a bond pad structure is depicted in
FIG. 1A . The illustration illustrates a design flaw in the bond pad structure that is overcome by the present invention, as will be described and illustrated with reference toFIGS. 2A-2I . - As shown in
FIG. 1A , asemiconductor wafer fragment 10 is shown as comprising asubstrate 12, which can comprise a semiconductor wafer substrate or the wafer along with various process layers formed thereon, including one or more semiconductor layers or other formations, and active or operable portions of semiconductor devices. Thebond pad structure 40 comprises afirst bond pad 28 and asecond bond pad 30, each formed from two overlying stacks of metal, although additional layers of metal can be utilized. - Referring to
FIG. 1A , in fabricating thebond pad structure 40, afirst metal layer 14 has been deposited onto thesubstrate 12 and patterned by dry etching resulting in alower metal layer 16 a of thefirst bond pad 28, and alower metal layer 16 b of thesecond bond pad 30, having aspace 18 thereinbetween. Adielectric layer 20 such as SiO2 has been deposited over thelower metal layers space 18 to electrically isolate the twolower metal layers lower metal layers second metal layer 24. - Referring now to
FIG. 1B , thedielectric layer 20 has been etched to provide vias or openings 22 to allow electrical connection between the first and second metal layers 14, 24. Asecond metal layer 24 has been deposited over thedielectric layer 20 and into theopenings - As shown in
FIG. 1C , thesecond metal layer 24 has been patterned by dry etching to form anupper metal layer 26 a of thefirst bond pad 28 and anupper metal layer 26 b of thesecond bond pad 30, which are separated by aspace 32. In addition, apassivation layer 34 has been put down on the wafer surface to seal the device structures from contamination and moisture, and as a scratch protection layer. - In a conventional approach, as seen in
FIG. 1D , anopening 36 has been etched into thepassivation layer 34 to expose the set ofbond pads bond pad structure 40. - A disadvantage of the construction shown in
FIG. 1D , is that, due to the alignment of the upper and lower metal layers of thebond pads dielectric material 20, between the twobond pads opening 38 down to thesubstrate 12. This exposure of thesubstrate 12 can result in a short on the die and device failure. This problem is overcome by the present invention. - An embodiment of the method of the present invention is illustrated with reference to
FIGS. 2A-2I , in forming a set of bond pads similar to that described with reference toFIGS. 1A-1C . Referring toFIG. 2A , asemiconductor wafer fragment 10′ is shown at a preliminary processing step. Thewafer fragment 10′ is shown as comprising asubstrate 12′, similar towafer fragment 10 with various process layers formed thereon. - As shown, a
first metal layer 14′ has been deposited onto thesubstrate 12′. Preferably, thefirst metal layer 14′ is formed from aluminum, aluminum alloys, titanium tungsten (Ti:W) alloys, platinum, copper, refractory metal silicides or other metals or metal alloys. Thefirst metal layer 14′ can be deposited, for example, by CVD or other method known and used in the art. Thefirst metal layer 14′ is in electrical contact with active areas in thesubstrate 12′. Eachpad 28′, 30′ is connected to its own set of devices, which are combined after bonding of thepads 28′, 30′. - According to the invention, the
first metal layer 14′ is masked and patterned by dry etching to form alower metal layer 16 a′ of thefirst bond pad 28′, and alower metal layer 16 b′ of thesecond bond pad 30′, having aspace 18′ thereinbetween, as illustrated inFIG. 2B . The patterning of thefirst metal layer 14′ is such that a lower metal layer of one of the bond pads extends beneath the upper metal layer of the other bond pad. As depicted, thefirst metal layer 14′ has been patterned and etched such that thelower metal layer 16 b′ of thesecond bond pad 30′ will extend underneath the subsequently formedupper metal layer 26 a′ of thefirst bond pad 28′. - As shown in
FIG. 2C , adielectric layer 20′ such as SiO2 is then deposited over thefirst metal layer 14′ and into thespace 18′ to electrically isolate the twolower metal layers 16 a′, 16 b′, and to isolate thefirst metal layer 14′ from the subsequently depositedsecond metal layer 24′. - With reference to
FIG. 2D , thedielectric layer 20′ is selectively etched to provide openings or vias 22 a′, 22 b′ to expose each of the first andsecond metal portions 16 a′, 16 b′ of thefirst metal layer 14′. Theopenings 22 a′, 22 b′ can be formed by conventional masking and silicon etching techniques including, for example, photolithographic and plasma etching processes. The etchedopening 22 b′ to thelower metal layer 16 b′ is depicted as being larger in diameter than theopening 22 b′. With the formation of a larger diameter opening 22 b′ for thesecond bond pad 30′, the metal portion that is subsequently deposited into theopening 22 b′ is wider in diameter than the metal portion within the opening 22 a′. Theetched openings 22 a′, 22 b′ can be any proportion to each other to suit the particular need, including equal in diameter. - As shown in
FIG. 2E , asecond metal layer 24′ is then deposited into theopenings 22 a′, 22 b′ and as a layer over theinsulative dielectric layer 20′. Thesecond metal layer 24′ can comprise the same or different metal as thefirst metal layer 14′, being aluminum in the illustrated example. Preferably, thesecond metal layer 24′ is thicker than thefirst metal layer 14′ in order to reduce resistance in thesecond metal layer 24′. - Referring to
FIG. 2F , thesecond metal layer 24′ is then patterned and dry etched to form anupper metal layer 26 a′ of thefirst bond pad 28′ and anupper metal layer 26 b′ of thesecond bond pad 30′, which are separated by aspace 32′ thereinbetween. The upper metal layers 26 a′, 26 b′ of the first andsecond bond pads 28′, 30′ are depicted as generally comprising about the same relative area, but can be any proportion to each as desired. - As depicted, the
lower metal layer 16 b′ of thesecond bond pad 30′ extends underneath theupper metal layer 26 a′ of thefirst bond pad 28′ to provide an interwoven or staggered layered structure. In another embodiment depicted inFIG. 2F (a), thelower metal layer 16 a′ of thefirst bond pad 28′ can be patterned and etched to extend beneath theupper metal layer 26 b′ of thesecond bond pad 30′. Thebond pads 28′, 30′ can also comprise additional stacked metal layers (e.g.,lower metal layers 16 a 1′, 16 a 2′, 16 b 1′, 16 b 2′) that can be formed to provide a staggered construction, as illustrated in FIGS. 2F(b) and 2F(c). - As
FIG. 2G illustrates, aprotective passivation layer 34′ is then formed over thesemiconductor wafer 10′. Thepassivation layer 34′, such as CVD PSG or plasma-enhanced CVD silicon nitride, is put down on the wafer surface to seal the device structures from contamination and moisture, and as a scratch protection layer. Thepassivation layer 34′ can also be fabricated, for example, from polyimide, acrylate, epoxy potting compound, acrylic, silicone, polyurethane or other resin, among other protective coating materials, using conventional methods in the art including spin coating, spraying, flow coating, brush coating, among other application techniques. - Referring now to
FIG. 2H , thepassivation layer 34′ is then masked and etched by conventional photolithography methods to form a bond pad opening 36′ to expose the upper metal layers 26 a′, 26 b′ of each of thefirst bond pad 28′ and thesecond bond pad 30′. The exposedbond pads 28′, 30′ are typically about 100 by 100 μm in size and separated by aspace 32′, for example, of about 0.5 μm, or other minimum space or distance allowable for the metal that is utilized. - As with the
bond pad structure 40 described with reference toFIGS. 1A-1C , etching of thepassivation layer 34′ also results in anopening 36′ being formed through thedielectric layer 20′ between the first andsecond bond pads 28′, 30′. However, advantageously, the offsetting of thelower metal layer 16 b′ of thesecond bond pad 30′ to extend underneath theupper metal layer 26 a′ of thefirst bond pad 28′, serves as an etch block during the passivation layer etch, thereby preventing theinsulation layer 20′ between the two bond pads from being etched down to thesubstrate 12′. - Referring now to
FIG. 2I , abonding wire 42′ can then be connected (bonded) to the metal of each of the bond pads and then to the chip package (not shown). In this way, electrical connections are established from the combined pads to an external electrical connection (i.e., the package leads) or to establish an internal-only operational function. During the bonding step, aconductive material 44′ such as a solder material attaching thewire 42′ to the bond pads can be flowed across the surface of the first andsecond bond pads 28′, 30′ and into thespace 38′ to connect the two bond pads. Thebonding wire 42′ is not required in all applications, in which case a conductive material (e.g., solder) can be applied to join the pads together. - The
bond pad structure 40′ is useful in numerous applications including enable operations, supplying and/or retrieving data, powering, grounding, testing circuitry, among other functions. For example, methods of testing an integrated circuit using a test enable bond pad are generally described, for example, in U.S. Pat. Nos. 6,240,535 and 5,796,746 (Farnworth et al., to Micron Technology, Inc.). The integrated circuit (IC) module (not shown) generally includes a terminal receiving a test mode signal, and an IC die having a function circuit and a bond pad. A switching device such as a fuse that is blown or a transistor that is deactivated once testing is complete, is connected with the test mode bond pad between the terminal and the function circuit to conduct the test mode signal to the function circuit. The test mode bond pad is connected to the function circuit and enables a test mode in an I.C. die. An impedance device such as a resistor or anti-fuse, connected between the function circuit and an operational mode signal, supports a difference in voltages between the test mode signal at the function circuit and the operation mode signal. Briefly, a supply voltage is applied to the test mode bond pad, and the function circuit responds to the test mode signal by initiating a test mode in the die to test the circuitry thereon. Once testing of the die is complete, a voltage is applied to disable the test mode, and the impedance device then conducts the operation mode signal to the function circuit. The function circuit responds to the operational mode signal by entering an operational mode in the die in which the die operates in accordance with its intended normal function. Such a set-up allows dice packaged in IC modules to be tested after packaging. A drawback of the described set-up is that in blowing the fuses or using a high voltage to disable the transistor, leakage problems can result. - In an exemplary bond pad structure according to the invention for use in testing and operating circuitry, the
first bond pad 28′ can comprise an operational mode bond pad that functions in an operational mode. Thesecond bond pad 30′ can comprise a test mode bond pad that functions initially in a test mode for testing of circuitry and subsequently, upon completion of the circuit testing and its connection to thefirst bond pad 28′, in an operational mode as a single unit with thefirst bond pad 28′. The connection between the first andsecond bond pads 28′, 30′ can be performed by applying aconductive material 44′ (e.g., solder) over at least a portion of each of thebond pads 28′, 30′ to form an extension between the two pads. It is understood that the first bond pad can be a test mode bond pad and the second bond pad can be an operational mode bond pad. Such a structure is useful for testing an integrated circuit, and functioning in an operational mode once the individual bond pads are connected. The separation of the first and thesecond bond pads 28′, 30′ avoids leakage problems that can be caused by high voltage that is applied when the fuse or antifuse is blown at the end of a test operation. - In compliance with the statute, the invention has been described in language more or less specific as to structural and methodical features. It is to be understood, however, that the invention is not limited to the specific features shown and described, since the means herein disclosed comprise preferred forms of putting the invention into effect. The invention is, therefore, claimed in any of its forms or modifications within the proper scope of the appended claims appropriately interpreted in accordance with the doctrine of equivalents.
Claims (30)
1. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a test mode signal to a first bond pad of a die to supply said test mode signal to test mode function circuitry of the die configured to initiate a test mode in the die; the die comprising the first die pad and a second bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer overlying the die, each of the bond pads comprising an upper metal layer overlying and connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad connected to the test mode function circuitry, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
upon completion of the test sequence, disabling the connection of the first bond pad with said test mode function circuitry;
interconnecting the first and second bond pads with a conductive material to form a single pad unit; and
initiating an operational sequence in the die by applying an operational signal to at least one of the first and second bond pads of the single pad unit.
2. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by applying a signal to a first bond pad of the die to supply said test mode signal to test mode function circuitry of the die configured to initiate a test mode in the die; the die comprising the first die pad and a second bond pad, said bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of the bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad connected to the test mode function circuitry of the die, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
initiating a test sequence on circuitry of the die by applying a signal to the first bond pad to conduct said signal to the test mode function circuitry;
terminating the test sequence by applying a signal to the first bond pad to disable the connection of the first bond pad with said test mode function circuitry;
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit; and
initiating an operational sequence in the die by applying a signal to at least one of the first and second bond pads of the single pad unit to conduct said signal to the operational mode function circuitry.
3. The method of claim 2 , wherein the electrically conductive material to connect the first and second bond pads comprises a solder material.
4. The method of claim 2 , further comprising, after the step of connecting the first and second bond pads, attaching a bonding wire to the conductive material.
5. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a signal to a test mode bond pad of the die to conduct said signal to test mode function circuitry of the die configured to initiate a test mode in the die; the die comprising the test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and within a single opening of a passivation layer on the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and the test mode bond pad connected to the test mode function circuitry, and the operational mode bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test sequence by disabling the connection of the test mode bond pad with said test mode function circuitry;
connecting the test mode bond pad to the operational mode bond pad with an electrically conductive material to form a single pad unit; and
initiating an operational sequence in the die by applying a signal to at least one of said bond pads of the single pad unit to conduct said signal to the operational mode function circuitry.
6. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test mode on circuitry of the die by conducting a signal to a test mode bond pad of the die to conduct said signal to test mode function circuitry of the die configured to initiate a test mode in the die; the die comprising the test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer on the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and the test mode bond pad connected to test mode function circuitry of the die configured to initiate a test mode in the die, and the operational mode bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test mode by applying a voltage to the test bond pad to disable the connection between the test mode bond pad and said test mode function circuitry;
connecting the test mode bond pad to the operational mode bond pad with an electrically conductive material to form a single pad unit; and
initiating an operational mode in the die by applying a signal to at least one of said bond pads of the single pad unit to conduct said signal to the operational mode function circuitry.
7. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a signal to a test mode bond pad of the die to conduct said signal through a switching device to test mode function circuitry of the die configured to initiate a test mode in the die; the die comprising the test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer on the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and the test mode bond pad connected via the switching device to the test mode function circuitry, and the operational mode bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test sequence by applying a voltage to the test bond pad to disable the switching device;
connecting the test mode bond pad to the operational mode bond pad with an electrically conductive material to form a single pad unit; and
initiating an operational sequence in the die by applying a signal to at least one of said bond pads of the single pad unit to conduct said signal to the operational mode function circuitry.
8. The method of claim 7 , wherein the switching device comprises a fuse or an antifuse.
9. The method of claim 7 , wherein the switching device comprises a transistor.
10. A method of testing and operating circuitry of a die, comprising the steps of:
applying a signal to a first bond pad of the die to conduct said signal to test mode function circuitry of the die to initiate a test sequence on circuitry of the die, the die comprising the first bond pad and a second bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer on the die, each of the bond pads comprising a plurality of interconnected and stacked lower metal layers connected to an upper metal layer, with at least one of the lower metal layers of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad connected to the test mode function circuitry, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
disabling the connection of the first bond pad with said test mode function circuitry to terminate the test sequence;
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit; and
applying a signal to at least one of the first and second bond pads of the single pad unit to conduct said signal to the operational mode function circuitry and initiate an operational sequence in the die.
11. The method of claim 10 , wherein the step of disabling comprises blowing a fuse.
12. The method of claim 10 , wherein the step of disabling comprises applying a voltage to the first bond pad.
13. A method of testing and operating circuitry of a die, comprising the steps of:
applying a signal to a first bond pad of the die to conduct said signal to test mode function circuitry of the die to initiate a test sequence on circuitry of the die, the die comprising the first bond pad and a second bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer on the die, each bond pad comprising an upper metal layer overlying and connected to two or more stacked lower metal layers, the upper metal layer of the first bond pad overlying at least one of the lower metal layers of the second bond pad, and the first bond pad connected to test mode function circuitry of the die configured to initiate a test mode in the die, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
disabling the connection of the first bond pad with said test mode function circuitry to terminate the test sequence;
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit; and
applying a signal to at least one of the first and second bond pads of the single pad unit to conduct said signal to the operational mode function circuitry and initiate an operational sequence in the die.
14. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a signal to a test mode bond pad and test mode function circuitry of the die, the die comprising the test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer overlying the die, each of said bond pads comprising an upper metal layer connected to two or more stacked and interconnected lower metal layers, the upper metal layer of one of said bond pads overlapping at least one of the lower metal layers of the other of said bond pads, and the test mode bond pad connected to the test mode function circuitry, and the operational mode bond pad connected to operational mode function circuitry of the die configured to initiate an operational sequence in the die;
terminating the test sequence by disabling the connection between the test mode bond pad and the test mode function circuitry;
connecting the test mode bond pad to the operational mode bond pad with an electrically conductive material to form a single pad unit; and
initiating an operational sequence in the die by applying a signal to at least one of the test mode bond pad and the operational mode bond pad of the single pad unit, to conduct said signal to the operational mode function circuitry.
15. A method of testing and operating circuitry of a die, comprising the steps of:
applying a signal to a first bond pad of the die to conduct said signal to test mode function circuitry of the die and initiate a test sequence on circuitry of the die, the die comprising the first bond pad and a second bond pad, said bond pads being unconnected and adjacently situated within a single opening of a passivation layer on the die, each bond pad comprising an upper metal layer conductively connected to a lower metal layer with an insulating layer situated between said upper and lower metal layers, and a lower metal layer of one bond pad extending underneath the upper metal layer of the other bond pad, and the first bond pad but not the second bond pad connected to said test mode function circuitry of the die, and the second bond pad but not the first bond pad connected to an operational mode function circuitry of the die;
disabling the connection of the first bond pad with said test mode function circuitry to terminate the test sequence;
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit; and
applying a signal to at least one of the first and second bond pads of the single pad unit to conduct said signal to the operational mode function circuitry and initiate an operational sequence in the die.
16. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a signal to the first bond pad and the test mode function circuitry;
initiating a test sequence on circuitry of the die by conducting a signal to a first bond pad and test mode function circuitry of the die, the die comprising separate first and second bond pads that are unconnected and adjacently situated within a single opening of a passivation layer on the die, each of said bond pads comprising a stacked upper metal layer connected to a lower metal layer, and an insulating layer situated therebetween, the metal layers of each bond pad connected by a conductive contact extending through the insulating layer, and the lower metal layer of one bond pad extending under the upper metal layer of the other bond pad, and the first bond pad but not the second bond pad connected to said test mode function circuitry of the die, and the second bond pad but not the first bond pad connected to an operational mode function circuitry of the die;
terminating the test sequence by disabling a connection between the first bond pad and the test mode function circuitry;
connecting the first bond pad and the second bond pad with an electrically conductive material to form a single pad unit; and
initiating an operational sequence in the die by applying a signal to at least one of the first and second bond pads of the single pad unit to conduct said signal to the operational mode function circuitry.
17. A method of testing and operating circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a signal to a first bond pad to conduct said signal to test mode function circuitry of the die, the die comprising the first bond pad and a second bond pad, said bond pads being electrically separate and within a single opening in a passivation layer on the die, each of the bond pads comprising a stacked upper metal layer connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad connected to said test mode function circuitry of the die, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test sequence by applying disabling the connection of the first bond pad with said test mode function circuitry;
connecting the first bond pad with the second bond pad with an electrically conductive material to form a single pad unit;
connecting a bonding wire to the conductive material; and
initiating an operational sequence in the die by applying a signal to the single pad unit to conduct said signal to the operational mode function circuitry.
18. A method of testing circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by applying a signal to a first bond pad to conduct said signal to test mode function circuitry of the die, the die comprising the first bond pad and a second bond pad, said bond pads being electrically separate and within a single opening of a passivation layer on the die, each of the bond pads comprising a stacked upper metal layer connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad connected to said test mode function circuitry of the die configured, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test sequence by disabling the connection of the first bond pad with said test mode function circuitry; and
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit, wherein applying a signal to the single pad unit conducts said signal to the operational mode function circuitry to initiate an operational sequence in the die.
19. The method of claim 18 , wherein the electrically conductive material to connect the first and second bond pads comprises a solder material.
20. The method of claim 18 , further comprising, after connecting the first and second bond pads, connecting a bonding wire to the conductive material.
21. A method of testing circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by conducting a signal to a test mode bond pad to supply said signal to test mode function circuitry of the die, the die comprising the test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and within a single opening of a passivation layer on the die, each of said bond pads comprising an upper metal layer and a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and the test mode bond pad connected to said test mode function circuitry of the die, and the operational mode bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test sequence by disabling the connection of the test mode bond pad with said test mode function circuitry;
connecting the test mode bond pad to the operational mode bond pad with an electrically conductive material to form a single pad unit; and
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit, wherein applying a signal to the single pad unit conducts said signal to the operational mode function circuitry to initiate an operational sequence in the die.
22. A method of testing circuitry of a die, comprising the steps of:
applying a signal to a first bond pad of the die to conduct said signal to test mode function circuitry of the die to initiate a test sequence on circuitry of the die; the die comprising the first bond pad and a second bond pad, said bond pads being electrically separate and within a single opening of a passivation layer on the die, each of the bond pads comprising a plurality of interconnected and stacked lower metal layers connected to an upper metal layer, with at least one of the lower metal layers of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad connected to the test mode function circuitry of the die, and the second bond pad connected to operational mode function circuitry of the die configured to initiate an operational mode in the die;
disabling the connection of the first bond pad with said test mode function circuitry to terminate the test sequence;
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit, wherein applying a signal to the single pad unit conducts said signal to the operational mode function circuitry to initiate an operational sequence in the die.
23. A method of testing circuitry of a die, comprising the steps of:
initiating a test sequence on circuitry of the die by applying a signal to a first bond pad to conduct said signal to test mode function circuitry of the die, the die comprising the first bond pad and a second bond pad, said bond pads being electrically separate and situated within a single opening of a passivation layer on the die, each of the bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and the first bond pad but not the second bond pad connected to the test mode function circuitry of the die, and the second bond pad but not the first bond pad connected to an operational mode function circuitry of the die configured to initiate an operational mode in the die;
terminating the test sequence by applying a signal to the first bond pad to disable the connection of the first bond pad with said test mode function circuitry; and
connecting the first bond pad to the second bond pad with an electrically conductive material to form a single pad unit, wherein applying a signal to the single pad unit conducts said signal to the operational mode function circuitry to initiate an operational sequence in the die.
24. A die, comprising:
a test mode function circuitry configured to initiate a test sequence on circuitry of the die;
an operational mode function circuitry configured to initiate an operational mode in the die; and
first and second bond pads, said bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of the bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and
the first bond pad connected to the test mode function circuitry of the die, and the second bond pad connected to the operational mode function circuitry of the die.
25. A die, comprising:
a test mode function circuitry configured to initiate a test sequence on circuitry of the die;
an operational mode function circuitry configured to initiate an operational mode in the die; and
first and second bond pads, said bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and
the first bond pad but not the second bond pad connected to the test mode function circuitry of the die, and the second bond pad but not the first bond pad connected to the operational mode function circuitry of the die.
26. A die, comprising:
a test mode function circuitry configured to initiate a test mode on circuitry of the die;
an operational mode function circuitry configured to initiate an operational mode on circuitry of the die; and
first and second bond pads, the bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of the bond pads comprising a plurality of interconnected and stacked lower metal layers connected to an upper metal layer, with at least one of the lower metal layers of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and
the first bond pad connected to the test mode function circuitry of the die, and the second bond pad connected to the operational mode function circuitry of the die.
27. A die, comprising:
a test mode function circuitry configured to initiate a test sequence in the die;
an operational mode function circuitry configured to initiate an operational mode in the die; and
first and second bond pads, the bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of the bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of the bond pads extending underneath the upper metal layer of the other of the bond pads, and
the first bond pad connected to the test mode function circuitry of the die, and the second bond pad connected to the operational mode function circuitry of the die.
28. A die, comprising:
a test mode function circuitry configured to initiate a test sequence in the die;
an operational mode function circuitry configured to initiate an operational mode in the die; and
a first bond pad and a second bond pad, said bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and
the first bond pad but not the second bond pad connected to the test mode function circuitry of the die, and the second bond pad but not the first bond pad connected to the operational mode function circuitry of the die.
wherein, when the connection of the first bond pad to the test mode function circuitry is disabled, and the first bond pad and the second bond pad are connected by a conductive material, said bond pads operate as a single unit to receive and conduct a signal only to the operational mode function circuitry of the die.
29. A die, comprising:
a test mode function circuitry configured to initiate a test sequence in the die;
an operational mode function circuitry configured to initiate an operational mode in the die; and
a test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and
the test mode bond pad connected to the test mode function circuitry of the die, and the operational mode bond pad connected to the operational mode function circuitry of the die.
30. A die, comprising:
a test mode function circuitry configured to initiate a test sequence in the die;
an operational mode function circuitry configured to initiate an operational mode in the die; and
a test mode bond pad and an operational mode bond pad, said bond pads being electrically separate and within a single opening of a passivation layer overlying the die, each of said bond pads comprising an upper metal layer connected to a lower metal layer, the lower metal layer of one of said bond pads extending underneath the upper metal layer of the other of said bond pads, and
the test mode bond pad but not the operational mode bond pad connected to the test mode function circuitry of the die, and the operational mode bond pad but not the test mode bond pad connected to the operational mode function circuitry of the die.
wherein, when the connection of the test mode bond pad to the test mode function circuitry is disabled, and the test mode bond pad and the operation mode bond pad are connected by a conductive material, said bond pads operate as a single unit to receive and conduct a signal only to the operational mode function circuitry of the die.
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US11/485,002 US20060250139A1 (en) | 2001-08-10 | 2006-07-12 | Bond pad structure comprising multiple bond pads with metal overlap |
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US10/389,455 US7146722B2 (en) | 2001-08-10 | 2003-03-14 | Method of forming a bond pad structure |
US11/485,002 US20060250139A1 (en) | 2001-08-10 | 2006-07-12 | Bond pad structure comprising multiple bond pads with metal overlap |
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US10/389,455 Expired - Lifetime US7146722B2 (en) | 2001-08-10 | 2003-03-14 | Method of forming a bond pad structure |
US11/485,002 Abandoned US20060250139A1 (en) | 2001-08-10 | 2006-07-12 | Bond pad structure comprising multiple bond pads with metal overlap |
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US10/389,455 Expired - Lifetime US7146722B2 (en) | 2001-08-10 | 2003-03-14 | Method of forming a bond pad structure |
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Also Published As
Publication number | Publication date |
---|---|
US7146722B2 (en) | 2006-12-12 |
US20030030153A1 (en) | 2003-02-13 |
US20030153103A1 (en) | 2003-08-14 |
US7064447B2 (en) | 2006-06-20 |
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