Abstract: A specialized etching method for producing fine-geometry gold circuit structures. Production thereof is accomplished by maintaining a constant gold etching rate. Metal etching normally slows as the amount of dissolved gold (a reaction product of the etching process) increases. To remove the dissolved gold, one method involves cooling the etchant to precipitate a gold complex therefrom. The remaining, recovered etchant is then heated and made available for continued etching. Another method involves a cathode/anode assembly which is immersed in the etchant. Activation of the assembly recovers metallic gold and regenerates the etchant. These methods, when used continuously or periodically in a dip or spray etching system, maintain a constant etching rate. As a result, fine-geometry circuit structures may be accurately produced while minimizing material costs (e.g. etchant use) and minimizing the production of undesirable waste products and disposal expenses associated therewith.

Abstract: Method and apparatus for controlling the temperature of one or more electrical component chips positioned on a face of a substrate and for providing component-to-component electrical interconnect traces between the chips. One or a selected set of electrical interconnections, contained within the substrate and connected to a chip, is also connected to a column of high electrical and thermal conductivity material within the substrate that is in direct thermal contact with the working fluid in a heat pipe. The heat pipe is sealed and is contained in the substrate interior and is in electrical and thermal contact with the electronic components on a chip. The heat pipe working fluid receives heat from the electronic components through the thermally conducting column, changes phase through absorption of this heat, and transports the heat to heat dissipation means located elsewhere.

Abstract: Method and apparatus for controlling the temperature of one or more electrical component chips positioned on a face of a substrate and for providing component-to-component electrical interconnect traces between the chips. One or a selected set of electrical interconnections, contained within the substrate and connected to a chip, is also connected to a column of high electrical and thermal conductivity material within the substrate that is in direct thermal contact with the working fluid in a heat pipe. The heat pipe is sealed and is contained in the substrate interior and is in electrical and thermal contact with the electronic components on a chip. The heat pipe working fluid receives heat from the electronic components through the thermally conducting column, changes phase through absorption of this heat, and transports the heat to heat dissipation means located elsewhere.

Abstract: A method for producing insulated superconductor wire including the steps of a tubular glass preform, filling it with a superconductor material, suspending the preform within an oven to heat a section of the preform to approximately its softening point, and drawing the softened preform into a superconductor wire. A plastic coating can be applied to the wire to increase its durability. The completed wire preferably includes a superconductor core having its superconductor phase aligned with the longitudinal axis of the wire, a glass coating over the superconductor core, and a plastic coating over the glass coating.