Abstract: A multi-chip stack structure and method of fabrication are provided utilizing self-aligning electrical contact arrays. Two or more arrays of interconnection contacts are provided, with one array being a rough aligned contact array, and a second array being a high bandwidth contact array. The rough aligned contact array has larger contacts and at least a portion thereof which melts at a substantially lower temperature than the melting temperature of the contacts of the high bandwidth contact array. By positioning two integrated circuit chips in opposing relation with the arrays mechanically aligned therebetween, and applying heat to melt the contacts of the rough aligned array, the two chips will rotate to align the respective contacts of the high bandwidth contact arrays, thereby achieving improved connection reliability between the structures.

Abstract: A multi-chip stack structure and method of fabrication are provided utilizing self-aligning electrical contact arrays. Two or more arrays of interconnection contacts are provided, with one array being a rough aligned contact array, and a second array being a high bandwidth contact array. The rough aligned contact array has larger contacts and at least a portion thereof which melts at a substantially lower temperature than the melting temperature of the contacts of the high bandwidth contact array. By positioning two integrated circuit chips in opposing relation with the arrays mechanically aligned therebetween, and applying heat to melt the contacts of the rough aligned array, the two chips will rotate to align the respective contacts of the high bandwidth contact arrays, thereby achieving improved connection reliability between the structures.

Abstract: A multi-chip stack structure and method of fabrication are provided utilizing self-aligning electrical contact arrays. Two or more arrays of interconnection contacts are provided, with one array being a rough aligned contact array, and a second array being a high bandwidth contact array. The rough aligned contact array has larger contacts and at least a portion thereof which melts at a substantially lower temperature than the melting temperature of the contacts of the high bandwidth contact array. By positioning two integrated circuit chips in opposing relation with the arrays mechanically aligned therebetween, and applying heat to melt the contacts of the rough aligned array, the two chips will rotate to align the respective contacts of the high bandwidth contact arrays, thereby achieving improved connection reliability between the structures.

Abstract: Chip-on-chip interconnections of varied characteristics, such as varied diameters, heights and/or composition, are disclosed. A first chip-on-chip interconnection on a joining plane has a first characteristic (e.g., a first height) and a second chip-on-chip interconnection on the same joining plane has a second characteristic (e.g., a second height greater than the first height). The first and second characteristics of the chip-on-chip interconnections allow for chip-on-chip connections to other packages, substrates or chips of different levels and/or compositions.

Abstract: A method for forming a wirebond connection to an integrated circuit structure includes forming an insulative structure overlaying a corrosion susceptible metal wiring within the integrated circuit structure, defining a via through the insulative structure above a portion of the corrosion susceptible metal without exposing the portion of the corrosion susceptible metal, and attaching a wirebond material to the portion of the corrosion susceptible metal. The attaching process includes a preliminary process of exposing the portion of the corrosion susceptible metal. The attaching completely covers the portion of the corrosion susceptible metal.

Abstract: Thin-film microflex twisted-wire pair and other connectors are disclosed. Semiconductor packages include microflex technology that electrically connects at least one chip to another level of packaging. Microflex connectors, such as thin-film twisted-wire pair connectors according to the present invention provide superior electrical performance, which includes reduced line inductance, incorporation of integrated passive components, and attachment of discrete passive and active components to the microflex. All of these features enable operation of the chip at increased frequencies.

Abstract: Thin-film microflex twisted-wire pair and other connectors are disclosed. Semiconductor packages include microflex technology that electrically connects at least one chip to another level of packaging. Microflex connectors, such as thin-film twisted-wire pair connectors according to the present invention provide superior electrical performance, which includes reduced line inductance, incorporation of integrated passive components, and attachment of discrete passive and active components to the microflex. All of these features enable operation of the chip at increased frequencies.

Abstract: Through-chip conductors for low inductance chip-to-chip integration and off-chip connections in a semiconductor package is disclosed. A semiconductor device has active devices on the front surface, a first through-chip conductor having first electrical/physical characteristics passing from the front surface of the device to the back surface, a second through-chip conductor having second electrical/physical characteristics passing to the back surface, and an off-chip or chip-to-chip connector electrically connecting the active devices on the front surface to a different level of packaging.

Abstract: A multi-chip stack structure and method of fabrication are provided utilizing self-aligning electrical contact arrays. Two or more arrays of interconnection contacts are provided, with one array being a rough aligned contact array, and a second array being a high bandwidth contact array. The rough aligned contact array has larger contacts and at least a portion thereof which melts at a substantially lower temperature than the melting temperature of the contacts of the high bandwidth contact array. By positioning two integrated circuit chips in opposing relation with the arrays mechanically aligned therebetween, and applying heat to melt the contacts of the rough aligned array, the two chips will rotate to align the respective contacts of the high bandwidth contact arrays, thereby achieving improved connection reliability between the structures.

Abstract: Thin-film microflex twisted-wire pair and other connectors are disclosed. Semiconductor packages include microflex technology that electrically connects at least one chip to another level of packaging. Microflex connectors, such as thin-film twisted-wire pair connectors according to the present invention provide superior electrical performance, which includes reduced line inductance, incorporation of integrated passive components, and attachment of discrete passive and active components to the microflex. All of these features enable operation of the chip at increased frequencies.

Abstract: Thin-film microflex twisted-wire pair and other connectors are disclosed. Semiconductor packages include microflex technology that electrically connects at least one chip to another level of packaging. Microflex connectors, such as thin-film twisted-wire pair connectors according to the present invention provide superior electrical performance, which includes reduced line inductance, incorporation of integrated passive components, and attachment of discrete passive and active components to the microflex. All of these features enable operation of the chip at increased frequencies.

Abstract: Thin-film microflex twisted-wire pair and other connectors are disclosed. Semiconductor packages include microflex technology that electrically connects at least one chip to another level of packaging. Microflex connectors, such as thin-film twisted-wire pair connectors according to the present invention provide superior electrical performance, which includes reduced line inductance, incorporation of integrated passive components, and attachment of discrete passive and active components to the microflex. All of these features enable operation of a chip at increased frequencies.

Abstract: The advantages of the invention are realized by a chip-on-chip module having at least two fully functional chips, electrically connected together, and a chip-on-chip component connection/interconnection for electrically connecting the fully functional chips to external circuitry.

Abstract: Through-chip conductors for low inductance chip-to-chip integration and off-chip connections in a semiconductor package is disclosed. A semiconductor device has active devices on the front surface, a first through-chip conductor having first electrical/physical characteristics passing from the front surface of the device to the back surface, a second through-chip conductor having second electrical/physical characteristics passing to the back surface, and an off-chip or chip-to-chip connector electrically connecting the active devices on the front surface to a different level of packaging.

Abstract: Chip-on-chip interconnections of varied characteristics, such as varied diameters, heights and/or composition, are disclosed. A first chip-on-chip interconnection on a joining plane has a first characteristic (e.g., a first height) and a second chip-on-chip interconnection on the same joining plane has a second characteristic (e.g., a second height greater than the first height). The first and second characteristics of the chip-on-chip interconnections allow for chip-on-chip connections to other packages, substrates or chips of different levels and/or compositions.

Abstract: Through-chip conductors for low inductance chip-to-chip integration and off-chip connections in a semiconductor package is disclosed. A semiconductor device has active devices on the front surface, a first through-chip conductor having first electrical/physical characteristics passing from the front surface of the device to the back surface, a second through-chip conductor having second electrical/physical characteristics passing to the back surface, and an off-chip or chip-to-chip connector electrically connecting the active devices on the front surface to a different level of packaging.

Abstract: The advantages of the invention are realized by a chip-on-chip module having at least two fully functional chips, electrically connected together, and a chip-on-chip component connection/interconnection for electrically connecting the fully functional chips to external circuitry.

Abstract: Electronic semiconductor structures, and fabrication and sparing methods, each utilize an electrically programmable spare circuit incorporated with a multichip package. The programmable sparing capability in the multichip package is accomplished either with or without the inclusion of a spare chip(s). With a spare memory circuit, individual failed memory cells in the semiconductor chips of a stack can be functionally replaced by memory cells of the spare memory circuit subsequent to encapsulation and burn-in testing. With use of a spare chip, non-volatile sparing can occur subsequent to encapsulation and burn-in testing without physical rewiring of a wire bond connection. Specific details of alternate electronic semiconductor structures, and fabrication and sparing methods therefore, are set forth.

Abstract: Integrated Circuit ("IC") chips are formed with precisely defined edges and sizing. At the wafer processing level, trenches are lithographically etched in the kerf regions to define the edges of the IC chips on the wafer. The trenches are filled with insulating material, and upper level wiring and metallization is completed for the IC chips on the wafer. Further trenches are defined down to the filled previously formed trenches. The wafer is thinned from its bottom up to the filled trenches, and the insulating material therein is removed to separate the individual IC chips from the wafer. The precision of IC chip edge definition facilitates forming the IC chips into stacks more easily because many stack level alignment processes become unnecessary.

Abstract: Methods and apparatus are set forth for burn-in stressing and simultaneous testing of a plurality of semiconductor device chips laminated together in a stack configuration to define a multichip module. Testing is facilitated by connecting temporary interconnect wiring to an access surface of the multichip module. This temporary interconnect wiring electrically interconnects at least some semiconductor device chips within the module. Prior to burn-in stressing and testing, a separate electrical screening step occurs to identify any electrical defect in the connection between the temporary interconnect wiring and the multichip module. If an electrical defect is identified, various techniques for removing or isolating the defect are presented. Thereafter, burn-in stressing and simultaneous testing of the semiconductor chips within the multichip module occurs using the temporary interconnect wiring.