Abstract: A solution (10) including a solvent and a monomer is coated on an area of a surface (16) of a piezoelectric member (12) such that the solution (10) flows into one or more defects (18). At least some of the solvent is removed to form a monomer film (20) within a defect (18), and the monomer film (20) is polymerized within the defect to form a polymer film (22) within the defect (18).

Abstract: A photonic-crystal filament is formed by mixing a slurry comprising particles of substantially uniform size and a precursor material for a desired metal, urging the slurry through an orifice to force the particles and precursor material into a combination having a desired crystallographic configuration, drying the combination emerging from the orifice, and sintering the precursor material.

Abstract: A method of manufacturing a microelectronics device is provided, wherein the microelectronics device is formed on a substrate having a frontside and a backside. The method comprises forming a circuit element on the frontside of the substrate from a plurality of layers deposited on the frontside of the substrate, wherein the plurality of layers includes an intermediate electrical contact layer, and forming an interconnect structure after forming the electrical contact layer. The interconnect structure includes a contact pad formed on the backside of the substrate, and a through-substrate interconnect in electrical communication with the contact pad, wherein the through-substrate interconnect extends from the backside of the substrate to the electrical contact layer.

Abstract: A photonic-crystal filament is formed by mixing a slurry comprising particles of substantially uniform size and a precursor material for a desired metal, urging the slurry through an orifice to force the particles and precursor material into a combination having a desired crystallographic configuration, drying the combination emerging from the orifice, and sintering the precursor material.

Abstract: A method of manufacturing a microelectronics device is provided, wherein the microelectronics device is formed on a substrate having a frontside and a backside. The method comprises forming a circuit element on the frontside of the substrate from a plurality of layers deposited on the frontside of the substrate, wherein the plurality of layers includes an intermediate electrical contact layer, and forming an interconnect structure after forming the electrical contact layer. The interconnect structure includes a contact pad formed on the backside of the substrate, and a through-substrate interconnect in electrical communication with the contact pad, wherein the through-substrate interconnect extends from the backside of the substrate to the electrical contact layer.

Abstract: A method of forming a through-substrate interconnect for a circuit element in a microelectronics device is provided. The device is formed on a substrate having a frontside and a backside, and includes a circuit element formed on the frontside of the substrate connected to a contact pad formed on the backside of the substrate by the through-substrate interconnect. The method includes forming a first interconnect structure extending into the substrate from the frontside of the substrate, at least partially forming the circuit element such that the circuit element is in electrical communication with the first interconnect structure, and forming a second interconnect structure extending into the substrate from the backside of the substrate after forming the first interconnect structure such that the second interconnect structure is in electrical communication with the first interconnect structure.

Abstract: A method of forming a through-substrate interconnect for a circuit element in a microelectronics device is provided. The device is formed on a substrate having a frontside and a backside, and includes a circuit element formed on the frontside of the substrate connected to a contact pad formed on the backside of the substrate by the through-substrate interconnect. The method includes forming a first interconnect structure extending into the substrate from the frontside of the substrate, at least partially forming the circuit element such that the circuit element is in electrical communication with the first interconnect structure, and forming a second interconnect structure extending into the substrate from the backside of the substrate after forming the first interconnect structure such that the second interconnect structure is in electrical communication with the first interconnect structure.

Abstract: A method of manufacturing a microelectronics device is provided, wherein the microelectronics device is formed on a substrate having a frontside and a backside. The method comprises forming a circuit element on the frontside of the substrate from a plurality of layers deposited on the frontside of the substrate, wherein the plurality of layers includes an intermediate electrical contact layer, and forming an interconnect structure after forming the electrical contact layer. The interconnect structure includes a contact pad formed on the backside of the substrate, and a through-substrate interconnect in electrical communication with the contact pad, wherein the through-substrate interconnect extends from the backside of the substrate to the electrical contact layer.

Abstract: A method of forming solder bumps on a wafer. The wafer includes at least one substrate, a plurality of solder-wettable pads and a solder wettable retention ring about the periphery of the wafer. The method of forming solder bumps includes forming a non-solder-wettable mask on the wafer which includes a plurality of apertures which align with the solder-wettable pads, and the solder wettable retention ring surrounds the mask. The mask and wafer are positioned within an aperture of a stencil so that the solder wettable retention ring aligns with a gap between the periphery edge of the mask and an inside edge of the aperture of the stencil. Solder paste is applied to the mask so that the solder paste fills the apertures of the mask and the gap. The solder paste is reflowed forming solder bumps on the pads and a solder ring on the solder wettable retention ring. The mask is removed after formation of the solder bumps.

Abstract: A solder bump is stenciled onto a substrate, providing bumped substrate at pitches below 400 microns. The solder is applied through stencil/mask and paste method; the mask, however, remains attached to the substrate during reflow. Pitches of greater than 400 microns may also be obtained through the invention. The invention further provides for generation of uniform, controllable volume metal balls.

Abstract: A solder bump is stenciled onto a substrate, providing bumped substrate at pitches below 400 microns. The solder is applied through stencil/mask and paste method; the mask, however, remains attached to the substrate during reflow. Pitches of greater than 400 microns may also be obtained through the invention. The invention further provides for generation of uniform, controllable volume metal balls.

Abstract: A solder bump is stenciled onto a substrate, providing bumped substrate at pitches below 400 microns. The solder is applied through stencil/mask and paste method; the mask, however, remains attached to the substrate during reflow. Pitches of greater than 400 microns may also be obtained through the invention. The invention further provides for generation of uniform, controllable volume metal balls.

Abstract: A solder bump is stenciled into a substrate, providing bumped substrate at pitches below 400 microns. The solder is applied through stencil/mask and paste method; the mask, however, remains attached to the substrate during reflow. Pitches of greater than 400 microns may also be obtained through the invention.