Abstract: Methods of fabricating multi-die assemblies including a wafer segment having no integrated circuitry thereon and having a plurality of vertically stacked dice thereon electrically interconnected by conductive through vias, resulting multi-die assemblies, and semiconductor devices comprising such multi-die assemblies. The wafer segment may function as a heat sink to enhance heat transfer from the stacked dice in the resulting multi-die assembly. The die stacks are fabricated at the wafer level on a base wafer, from which the wafer segment and die stacks are singulated after at least peripheral encapsulation.

Abstract: Methods of fabricating multi-die assemblies including a wafer segment having no integrated circuitry thereon and having a plurality of vertically stacked dice thereon electrically interconnected by conductive through vias, resulting multi-die assemblies, and semiconductor devices comprising such multi-die assemblies. The wafer segment may function as a heat sink to enhance heat transfer from the stacked dice in the resulting multi-die assembly. The die stacks are fabricated at the wafer level on a base wafer, from which the wafer segment and die stacks are singulated after at least peripheral encapsulation.

Abstract: Methods for forming semiconductor device packages include applying a photoimageable dielectric adhesive material to a major surface of a semiconductor die and at least partially over conductive elements on the semiconductor die. The photoimageable dielectric adhesive material may be removed from over the conductive elements. The conductive elements are aligned with and bonded to bond pads of a substrate, and the semiconductor die and the substrate are adhered with the photoimageable dielectric adhesive material. A semiconductor device package includes at least one semiconductor die including conductive structures thereon, a substrate including bond pads thereon that are physically and electrically connected to the conductive structures, and a developed photoimageable dielectric adhesive material disposed between the semiconductor die and the substrate around and between adjacent conductive structures.

Abstract: Methods of fabricating multi-die assemblies including a wafer segment having no integrated circuitry thereon and having a plurality of vertically stacked dice thereon electrically interconnected by conductive through vias, resulting multi-die assemblies, and semiconductor devices comprising such multi-die assemblies. The wafer segment may function as a heat sink to enhance heat transfer from the stacked dice in the resulting multi-die assembly. The die stacks are fabricated at the wafer level on a base wafer, from which the wafer segment and die stacks are singulated after at least peripheral encapsulation.

Abstract: Methods of fabricating multi-die assemblies including a base semiconductor die bearing a peripherally encapsulated stack of semiconductor dice of lesser lateral dimensions, the dice vertically connected by conductive elements between the dice, resulting assemblies, and semiconductor devices comprising such assemblies.

Abstract: Methods of fabricating multi-die assemblies including a wafer segment having no integrated circuitry thereon and having a plurality of vertically stacked dice thereon electrically interconnected by conductive through vias, resulting multi-die assemblies, and semiconductor devices comprising such multi-die assemblies. The wafer segment may function as a heat sink to enhance heat transfer from the stacked dice in the resulting multi-die assembly. The die stacks are fabricated at the wafer level on a base wafer, from which the wafer segment and die stacks are singulated after at least peripheral encapsulation.

Abstract: Stenciling machines and methods for forming solder balls on microelectronic workpieces are disclosed herein. In one embodiment, a method for depositing and reflowing solder paste on a microelectronic workpiece having a plurality of dies includes positioning a stencil having a plurality of apertures at least proximate to the workpiece. The method further includes placing discrete masses of solder paste into the apertures and reflowing the discrete masses of solder paste while the stencil is positioned at least proximate to the workpiece and while the discrete masses are in the apertures. In another embodiment of the invention, a stenciling machine for depositing and reflowing solder paste on the microelectronic workpiece includes a heater for reflowing the solder paste, a stencil having a plurality of apertures, and a controller operatively coupled to the heater and the stencil. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: Stenciling machines and methods for forming solder balls on microelectronic workpieces are disclosed herein. In one embodiment, a method for depositing and reflowing solder paste on a microelectronic workpiece having a plurality of dies includes positioning a stencil having a plurality of apertures at least proximate to the workpiece. The method further includes placing discrete masses of solder paste into the apertures and reflowing the discrete masses of solder paste while the stencil is positioned at least proximate to the workpiece and while the discrete masses are in the apertures. In another embodiment of the invention, a stenciling machine for depositing and reflowing solder paste on the microelectronic workpiece includes a heater for reflowing the solder paste, a stencil having a plurality of apertures, and a controller operatively coupled to the heater and the stencil. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: Stenciling machines and methods for forming solder balls on microelectronic workpieces are disclosed herein. In one embodiment, a method for depositing and reflowing solder paste on a microelectronic workpiece having a plurality of dies includes positioning a stencil having a plurality of apertures at least proximate to the workpiece. The method further includes placing discrete masses of solder paste into the apertures and reflowing the discrete masses of solder paste while the stencil is positioned at least proximate to the workpiece and while the discrete masses are in the apertures. In another embodiment of the invention, a stenciling machine for depositing and reflowing solder paste on the microelectronic workpiece includes a heater for reflowing the solder paste, a stencil having a plurality of apertures, and a controller operatively coupled to the heater and the stencil. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: A method and a system for attaching semiconductor components to a substrate are provided. In the illustrative embodiment the substrate is a leadframe, and the components are semiconductor dice or packages contained on a component substrate such as a wafer. The method includes the steps of holding and dicing the component substrate using a radiation sensitive tape. The method also includes the steps of providing a component attach system having a radiation curing system, and then performing local curing of the dicing tape during a component attach step using the component attach system. The system includes the component attach system which includes a stepper mechanism for stepping the component substrate, and a component attach mechanism having an ejector pin for pushing the components one at a time from the tape and a pick and place mechanism for placing the components on the substrate.

Abstract: A method and a system for attaching semiconductor components to a substrate are provided. In the illustrative embodiment the substrate is a leadframe, and the components are semiconductor dice or packages contained on a component substrate such as a wafer. The method includes the steps of holding and dicing the component substrate using a radiation sensitive tape. The method also includes the steps of providing a component attach system having a radiation curing system, and then performing local curing of the dicing tape during a component attach step using the component attach system. The system includes the component attach system which includes a stepper mechanism for stepping the component substrate, and a component attach mechanism having an ejector pin for pushing the components one at a time from the tape and a pick and place mechanism for placing the components on the substrate.

Abstract: An apparatus and method for attaching a flip chip configured semiconductor die to a substrate as well as removing the die and replacing it on the substrate with another flip chip-configured semiconductor die by way of an electrically resistive thermal supply circuit that provides heat to soften or melt an electrical connection material of discrete conductive elements connecting the two components, as well as providing heat to release a dielectric underfill material, if present. Methods for designing a thermal supply circuit and are also disclosed. Semiconductor die and substrate configurations incorporating thermal supply circuits as well as thermal supply circuit configurations and design approaches are also disclosed.

Abstract: Stenciling machines and methods for forming solder balls on microelectronic workpieces are disclosed herein. In one embodiment, a method for depositing and reflowing solder paste on a microelectronic workpiece having a plurality of dies includes positioning a stencil having a plurality of apertures at least proximate to the workpiece. The method further includes placing discrete masses of solder paste into the apertures and reflowing the discrete masses of solder paste while the stencil is positioned at least proximate to the workpiece and while the discrete masses are in the apertures. In another embodiment of the invention, a stenciling machine for depositing and reflowing solder paste on the microelectronic workpiece includes a heater for reflowing the solder paste, a stencil having a plurality of apertures, and a controller operatively coupled to the heater and the stencil. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: A stacked semiconductor package including a plurality of stacked semiconductor devices on a substrate, and a method of forming the same. The semiconductor devices are stacked in an active surface-to-backside configuration. The top semiconductor die is flipped over to face the active surface of the semiconductor die directly below. An electrical connector can extend from a bond pad on the top semiconductor die to a redistribution circuit on the semiconductor die below. The redistribution circuit can be electrically connected to a substrate. Alternatively, an electrical connector extends from a bond pad on top semiconductor die to a bond pad on a substrate.

Abstract: Stenciling machines and methods for forming solder balls on microelectronic workpieces are disclosed herein. In one embodiment, a method for depositing and reflowing solder paste on a microelectronic workpiece having a plurality of dies includes positioning a stencil having a plurality of apertures at least proximate to the workpiece. The method further includes placing discrete masses of solder paste into the apertures and reflowing the discrete masses of solder paste while the stencil is positioned at least proximate to the workpiece and while the discrete masses are in the apertures. In another embodiment of the invention, a stenciling machine for depositing and reflowing solder paste on the microelectronic workpiece includes a heater for reflowing the solder paste, a stencil having a plurality of apertures, and a controller operatively coupled to the heater and the stencil. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: A stacked semiconductor package including a plurality of stacked semiconductor devices on a substrate, and a method of forming the same. The semiconductor devices are stacked in an active surface-to-backside configuration. The top semiconductor die is flipped over to face the active surface of the semiconductor die directly below. An electrical connector can extend from a bond pad on the top semiconductor die to a redistribution circuit on the semiconductor die below. The redistribution circuit can be electrically connected to a substrate. Alternatively, an electrical connector extends from a bond pad on the top semiconductor die to a bond pad on a substrate.

Abstract: An apparatus and method for attaching a flip chip configured semiconductor die to a substrate as well as removing the die and replacing it on the substrate with another flip chip configured semiconductor die by way of an electrically resistive thermal supply circuit that provides heat to soften or melt an electrical connection material of discrete conductive elements connecting the two components, as well as providing heat to release a dielectric underfill material, if present. Methods for designing a thermal supply circuit and are also disclosed. Semiconductor die and substrate configurations incorporating thermal supply circuits as well as thermal supply circuit configurations and design approaches are also disclosed.

Abstract: Stenciling machines and methods for forming solder balls on microelectronic-workpieces are disclosed herein. In one embodiment, a method for depositing and reflowing solder paste on a microelectronic workpiece having a plurality of dies includes positioning a stencil having a plurality of apertures at least proximate to the workpiece. The method further includes placing discrete masses of solder paste into the apertures and reflowing the discrete masses of solder paste while the stencil is positioned at least proximate to the workpiece and while the discrete masses are in the apertures. In another embodiment of the invention, a stenciling machine for depositing and reflowing solder paste on the microelectronic workpiece includes a heater for reflowing the solder paste, a stencil having a plurality of apertures, and a controller operatively coupled to the heater and the stencil. The controller has a computer-readable medium containing instructions to perform the above-mentioned method.

Abstract: A method and a system for attaching semiconductor components to a substrate are provided. In the illustrative embodiment the substrate is a leadframe, and the components are semiconductor dice or packages contained on a component substrate such as a wafer. The method includes the steps of holding and dicing the component substrate using a radiation sensitive tape. The method also includes the steps of providing a component attach system having a radiation curing system, and then performing local curing of the dicing tape during a component attach step using the component attach system. The system includes the component attach system which includes a stepper mechanism for stepping the component substrate, and a component attach mechanism having an ejector pin for pushing the components one at a time from the tape and a pick and place mechanism for placing the components on the substrate.

Abstract: A method and a system for attaching semiconductor components to a substrate are provided. In the illustrative embodiment the substrate is a leadframe, and the components are semiconductor dice or packages contained on a component substrate such as a wafer. The method includes the steps of holding and dicing the component substrate using a radiation sensitive tape. The method also includes the steps of providing a component attach system having a radiation curing system, and then performing local curing of the dicing tape during a component attach step using the component attach system. The system includes the component attach system which includes a stepper mechanism for stepping the component substrate, and a component attach mechanism having an ejector pin for pushing the components one at a time from the tape and a pick and place mechanism for placing the components on the substrate.