Abstract: A stereolithographically fabricated marking for a semiconductor device component, such as a packaged or unpackaged semiconductor device or another substrate. When formed on a semiconductor device with a stereolithographically formed package structure, the marking may be integral with the package. The marking may be formed as apertures through or recesses in one or more stereolithographically fabricated layers of material, or the marking may include one or more stereolithographically fabricated layers that protrude from a surface of a semiconductor device component. Raised markings may also be formed on the surfaces of packaged or bare semiconductor device components. Alternatively, the marking may be fabricated separately from a semiconductor device component, then secured thereto. Methods for stereolithographically marking semiconductor device components are also disclosed.

Abstract: Methods for thinning a bumped semiconductor wafer, as well as methods for producing flip-chips of very thin profiles, are disclosed. According to the methods of the present invention, a mold compound is interspersed between conductive bumps on the active face of a wafer to provide support and protection for the wafer structure both during and after a process of removing the wafer's inactive back side silicon surface. The mold compound also serves to preserve the integrity of the conductively bumped aspects of the wafer during subsequent processing and may, after the wafer is diced, act as all or part of an underfill material for flip-chip applications.

Abstract: Dielectric rings are configured to be disposed around contact pads on a surface of a semiconductor device or another substrate. The rings may be fabricated or otherwise disposed around the contact pads of a semiconductor device or other substrate before or after conductive structures, such as solder balls, are secured to the contact pads. Upon connecting the semiconductor device face-down to a higher level substrate and establishing electrical communication between contact pads of the semiconductor device and contacts pads of the substrate, the rings prevent the material of solder balls protruding from the semiconductor device from contacting regions of the surface of the semiconductor device that surround the contact pads thereof. The rings may be preformed structures or fabricated on the surface of the semiconductor device or other substrate. For example, stereolithographic techniques may be used to form the rings.

Abstract: Stiffeners for tapes, films, or other connective structures, which are configured to be secured to a semiconductor device component, such as a semiconductor die or substrate, by tape-automated bonding processes, are fabricated by stereolithographic processes and may include one or two or more layers. The stiffeners are configured to prevent torsional flexion or bending of the connective structure to which they are to be secured. The stiffeners may reinforce sprocket or indexing holes in connective structures. The stiffeners may include apertures through which intermediate conductive elements or other structures secured to the connective structure may be exposed or protrude. The stereolithographic method for fabricating stiffeners may include use of a machine vision system that recognizes the position and orientation of one or more connective structures on which at least an element of each of the stiffeners is to be fabricated so that the application of material thereto may be controlled.

Abstract: Dielectric rings to be disposed around contact pads on a surface of a semiconductor device or another substrate and methods of fabricating and disposing the rings on semiconductor devices and other substrates are disclosed. One or more of the rings may be positioned around the contact pads of a semiconductor device or other substrate before or after solder balls are secured to the contact pads. Upon reflowing the solder balls to connect the semiconductor device face-down to a higher level substrate, the rings prevent the reflowed solder from contacting regions of the surface of the semiconductor device that surround the contact pads thereof. The rings may be preformed structures which are attached to a surface of a semiconductor device or other substrate. Alternatively, the rings can be fabricated on the surface of the semiconductor device or other substrate. A stereolithographic method of fabricating the rings is disclosed.

Abstract: Stiffeners for tapes, films, or other connective structures, which are configured to be secured to a semiconductor device component, such as a semiconductor die or substrate, by tape-automated bonding processes, are fabricated by stereolithographic processes and may include one or two or more layers. The stiffeners are configured to prevent torsional flexion or bending of the connective structure to which they are to be secured. The stiffeners may reinforce sprocket or indexing holes in connective structures. The stiffeners may include apertures through which intermediate conductive elements or other structures secured to the connective structure may be exposed or protrude. The stereolithographic method for fabricating stiffeners may include use of a machine vision system that recognizes the position and orientation of one or more connective structures on which at least an element of each of the stiffeners is to be fabricated so that the application of material thereto may be controlled.

Abstract: Stiffeners for tapes, films, or other connective structures that are configured to be secured to a semiconductor device component, such as a semiconductor die or substrate, by tape-automated bonding processes. The stiffeners are fabricated by stereolithographic processes and may include one layer or two or more superimposed, contiguous, mutually adhered layers. The stiffeners are configured to prevent torsional flexion or bending of the connective structure to which they are to be secured. The stiffeners may include apertures through which intermediate conductive elements or other structures secured to the connective structure may be exposed or protrude. Stiffeners that reinforce sprocket or indexing holes in a connective structure are also disclosed.

Abstract: A method of making a semiconductor device assembly having a lead frame and a semiconductor device configured to be attached to each other is disclosed. An adhesive is applied at room temperature through a stencil to the lead frame. The semiconductor device is urged against the adhesive to effect the attachment between the semiconductor device and the lead frame. The adhesive preferably is from about 75 percent to about 95 percent isobutyl acetal diphenol copolymer and from about 25 percent to about 5 percent, respectively, of titanium oxide.

Abstract: A method for fabricating an interposer includes providing an interposer substrate with at least one slot or aperture therethrough and forming at least one upwardly protruding dam on the interposer substrate, adjacent to the slot or aperture. The upwardly protruding dam or dams may at least partially surround the slot or aperture. Accordingly, the upwardly protruding dam or dams may laterally confine encapsulant material over the slot or aperture and over any intermediate conductive elements extending through the slot or aperture. Programmed material consolidation processes, such as stereolithography, may be used to form the at least one upwardly protruding dam.

Abstract: Stiffeners for tapes, films, or other connective structures, which are configured to be secured to a semiconductor device component, such as a semiconductor die or substrate, by tape-automated bonding processes, are fabricated by stereolithographic processes and may include one or two or more layers. The stiffeners are configured to prevent torsional flexion or bending of the connective structure to which they are to be secured. The stiffeners may reinforce sprocket or indexing holes in connective structures. The stiffeners may include apertures through which intermediate conductive elements or other structures secured to the connective structure may be exposed or protrude. The stereolithographic method for fabricating stiffeners may include use of a machine vision system that recognizes the position and orientation of one or more connective structures on which at least an element of each of the stiffeners is to be fabricated so that the application of material thereto may be controlled.

Abstract: Stiffeners for tapes, films, or other connective structures, which are configured to be secured to a semiconductor device component, such as a semiconductor die or substrate, by tape-automated bonding processes, are fabricated by stereolithographic processes and may include one or two or more layers. The stiffeners are configured to prevent torsional flexion or bending of the connective structure to which they are to be secured. The stiffeners may reinforce sprocket or indexing holes in connective structures. The stiffeners may include apertures through which intermediate conductive elements or other structures secured to the connective structure may be exposed or protrude.

Abstract: Methods for finishing or refurbishing surfaces on protective covers encapsulating microelectronic dies. In one embodiment, a method for finishing a surface of a protective package on a microelectronic device includes abrading the surface of the package by engaging an abrasive media with the surface of the package, terminating the abrasion when a surface blemish has been at least partially removed from the package, and cleaning residual materials from the package after terminating the abrasion of the package surface. The abrasive media can include a fixed-abrasive member, a fixed-abrasive member and a solution, a non-abrasive member and a chemical solution having abrasive particles, or an abrasive blasting media.

Abstract: Stiffeners for tapes, films, or other connective structures that are configured to be secured to a semiconductor device component, such as a semiconductor die or substrate, by tape-automated bonding processes. The stiffeners are fabricated by stereolithographic processes and may include one layer or two or more superimposed, contiguous, mutually adhered layers. The stiffeners are configured to prevent torsional flexion or bending of the connective structure to which they are to be secured. The stiffeners may include apertures through which intermediate conductive elements or other structures secured to the connective structure may be exposed or protrude. Stiffeners that reinforce sprocket or indexing holes in a connective structures are also disclosed.

Abstract: A solder mask includes an opening through which intermediate conductive elements may be positioned between bond pads of a semiconductor die exposed through an aligned opening in a carrier substrate to which the solder mask is secured and corresponding contact areas of the carrier substrate. An assembly is formed by forming the solder mask on or securing the solder mask to the carrier substrate. The semiconductor die is attached to the carrier substrate such that bond pads of the semiconductor die are exposed through the aligned openings in the carrier substrate and solder mask. Intermediate conductive elements are used to electrically connect the bond pads to corresponding contact areas on the carrier substrate. An encapsulant material is introduced into an area defined by the solder mask and carrier substrate openings such that the intermediate conductive elements and semiconductor die surface within the aligned openings are encapsulated.

Abstract: A dam for substantially laterally confining a quantity of encapsulant material over a region of a substrate, such as an interposer. The dam is configured to protrude upwardly from a surface of the interposer or other substrate. The interposer may be positioned at least partially around a slot or aperture through the substrate so as to laterally confine encapsulant material over the slot or aperture and over any intermediate conductive elements extending through the slot or aperture. The dam may be fabricated by stereolithography. A package including the interposer, the dam, and a semiconductor die to which the interposer is secured may include a sealing element between the interposer and the active surface of the die. All or part of the sealing element may also be fabricated using stereolithography. Methods and systems using machine vision in conjunction with stereolithography equipment are also disclosed.

Abstract: A stereolithographically fabricated marking for a semiconductor device component, such as a packaged or unpackaged semiconductor device or another substrate. When formed on a semiconductor device with a stereolithographically formed package structure, the marking may be integral with the package. The marking may be formed as apertures through or recesses in one or more stereolithographically fabricated layers of material, or the marking may include one or more stereolithographically fabricated layers that protrude from a surface of a semiconductor device component. Raised markings may also be formed on the surfaces of packaged or bare semiconductor device components. Alternatively, the marking may be fabricated separately from a semiconductor device component, then secured thereto. Methods for stereolithographically marking semiconductor device components are also disclosed.

Abstract: A stereolithographically fabricated marking for a semiconductor device component, such as a packaged or unpackaged semiconductor device or another substrate. When formed on a semiconductor device with a stereolithographically formed package structure, the marking may be integral with the package. The marking may be formed as apertures through or recesses in one or more stereolithographically fabricated layers of material, or the marking may include one or more stereolithographically fabricated layers that protrude from a surface of a semiconductor device component. Raised markings may also be formed on the surfaces of packaged or bare semiconductor device components. Alternatively, the marking may be fabricated separately from a semiconductor device component, then secured thereto. Methods for stereolithographically marking semiconductor device components are also disclosed.

Abstract: A solder mask includes an opening through which intermediate conductive elements may be positioned between bond pads of a semiconductor die exposed through an aligned opening in a carrier substrate to which the solder mask is secured and corresponding contact areas of the carrier substrate. An assembly is formed by forming the solder mask on or securing the solder mask on the carrier substrate. The semiconductor die is then attached to the carrier substrate such that bond pads of the semiconductor die are exposed through the aligned openings in the substrate and solder mask. Intermediate conductive elements are then used to electrically connect the bond pads to corresponding contact areas on the substrate. An encapsulant material is introduced into an area defined by the solder mask and carrier substrate openings such that the intermediate conductive elements and semiconductor die surface within the aligned openings are encapsulated.

Abstract: Packaged microelectronic devices, methods of manufacturing packaged microelectronic devices, and method of mounting packaged microelectronic devices to printed circuit boards. One embodiment can include a die, an interposer substrate, a solder-ball, and a dielectric compound. The die can have an integrated circuit and at least one bond-pad coupled to the integrated circuit. The interposer substrate is coupled to the die and can have at least one ball-pad electrically coupled to the bond-pad on the die. The interposer substrate can also have a trace line adjacent to the ball-pad, and a solder-mask having an opening over the ball-pad. The solder-ball can contact the ball-pad in the opening. The dielectric compound can insulate the ball-pad and the solder-ball from an exposed portion of the adjacent trace line in the opening.

Abstract: A stencil for use in fabricating semiconductor devices is disclosed that has an aperture having a first portion extending from a first side thereof and a second portion extending from a second side thereof to minimize the shear stress between the material extruded therethrough and the stencil. The stencil allows for material to be extruded through the top of the stencil to the surface of the substrate and not contact the wall of the second portion of the aperture of the stencil. Since the material only contacts a small area of the first portion of the aperture near the top of the stencil, the material remains on the substrate and not in the aperture of the stencil.