Abstract: A support structure for use with a semiconductor substrate in thinning, or backgrinding, thereof, as well as during post-thinning processing of the semiconductor substrate includes a portion which extends substantially along and around an outer periphery of the semiconductor substrate to impart the thinned semiconductor substrate with rigidity. The support structure may be configured as a ring or as a member which substantially covers an active surface of the semiconductor substrate and forms a protective structure over each semiconductor device carried by the active surface.

Abstract: Methods for optimizing physical properties of selectively consolidatable materials, such as photoimageable materials, include mixing filler materials with the selectively consolidatable materials. The resulting compound has the desired physical property, as well as selective consolidatability. Examples of physical properties that may optimized in a selectively consolidatable compound by mixing a filler material with a selectively consolidatable material include, without limitation, coefficient of thermal expansion, rigidity, fracture toughness, thermal stability, and strength.

Abstract: Microelectronic devices, methods for packaging microelectronic devices, and methods for forming interconnects in microelectronic devices are disclosed herein. In one embodiment, a method comprises providing a microelectronic substrate having a front side and a backside. The substrate has a microelectronic die including an integrated circuit and a terminal operatively coupled to the integrated circuit. The method also includes forming a passage at least partially through the substrate and having an opening at the front side and/or backside of the substrate. The method further includes sealing the opening with a conductive cap that closes one end of the passage while another end of the passage remains open. The method then includes filling the passage with a conductive material.

Abstract: Microelectronic imagers and methods for packaging microelectronic imagers are disclosed herein. In one embodiment, a microelectronic imaging unit can include a microelectronic die, an image sensor, an integrated circuit electrically coupled to the image sensor, and a bond-pad electrically coupled to the integrated circuit. An electrically conductive through-wafer interconnect extends through the die and is in contact with the bond-pad. The interconnect can include a passage extending completely through the substrate and the bond-pad with conductive fill material at least partially disposed in the passage. An electrically conductive support member is carried by and projects from the bond-pad. A cover over the image sensor is coupled to the support member.

Abstract: Microelectronic imagers with prefabricated housings and methods of packaging microelectronic imagers are disclosed herein. In one embodiment, a microelectronic imager can include a microelectronic die, an image sensor, and an integrated circuit operatively coupled to the integrated circuit. The microelectronic imager also includes an optic unit having an optic member. The microelectronic imager further includes a prefabricated housing having a first mounting site and a second mounting site. The die is seated within the housing at the first mounting site and the optics unit is seated within the housing at the second mounting site in a fixed, preset position in which the optic member is situated at a desired location relative to the image sensor.

Abstract: Microelectronic devices, methods for packaging microelectronic devices, and methods for forming vias and conductive interconnects in microfeature workpieces and dies are disclosed herein. In one embodiment, a method includes forming a bond-pad on a die having an integrated circuit, the bond-pad being electrically coupled to the integrated circuit. A conductive line is then formed on the die, the conductive line having a first end portion attached to the bond-pad and a second end portion spaced apart from the bond-pad. The method can further include forming a via or passage through the die, the bond-pad, and the first end portion of the conductive line, and depositing an electrically conductive material in at least a portion of the passage to form a conductive interconnect extending at least generally through the microelectronic device.

Abstract: A support structure for use with a semiconductor substrate in thinning, or backgrinding, thereof, as well as during post-thinning processing of the semiconductor substrate includes a portion which extends substantially along and around an outer periphery of the semiconductor substrate to impart the thinned semiconductor substrate with rigidity. The support structure may be configured as a ring or as a member which substantially covers an active surface of the semiconductor substrate and forms a protective structure over each semiconductor device carried by the active surface. Assemblies that include the support structure and a semiconductor substrate are also within the scope of the present invention, as are methods for forming the support structures and thinning and post-thinning processes that include use of the support structures.