Abstract: A multi-layer structure including a first layer; a second layer, with a coefficient of thermal expansion different than a coefficient of thermal expansion of the first layer, a bulk modulus different than a bulk modulus of the first layer and a thermal conductivity different than a thermal conductivity of the first layer; a bonding layer, having an isostatic pressure versus temperature curve with one of the first layer and the second layer which is substantially similar to an isostatic pressure versus temperature curve of the first layer and the second layer, such that a substantially stress-free bond is formed between the first layer and the second layer; wherein the first layer, the second layer, and the bonding layer are arranged as a sandwich, with the bonding layer in between the first layer and the second layer.

Abstract: Cooling of densely packaged semiconductor devices is achieved by microchannels which extract heat by forced convection and the use of fluid coolant located as close as possible to the heat source. The microchannels maximize heat sink surface area and provides improved heat transfer coefficients, thereby allowing a higher power density of semiconductor devices without increasing junction temperature or decreasing reliability. In its preferred embodiment, a plurality of microchannels are formed directly in the substrate portion of a silicon or silicon carbide chip or die mounted on a ground plane element of a circuit board and where a liquid coolant is fed to and from the microchannels through the ground plane. The microchannels comprise a plurality of closed-ended slots or grooves of generally rectangular cross section. Fabrication methods include deposition and etching, lift-off processing, micromachining and laser cutting techniques.

Abstract: Cooling of densely packaged semiconductor devices is achieved by microchannels which extract heat by forced convection and the use of fluid coolant located as close as possible to the heat source. The microchannels maximize heat sink surface area and provides improved heat transfer coefficients, thereby allowing a higher power density of semiconductor devices without increasing junction temperature or decreasing reliability. In its preferred embodiment, a plurality of microchannels are formed directly in the substrate portion of a silicon or silicon carbide chip or die mounted on a ground plane element of a circuit board and where a liquid coolant is fed to and from the microchannels through the ground plane. The microchannels comprise a plurality of closed-ended slots or grooves of generally rectangular cross section. Fabrication methods include deposition and etching, lift-off processing, micromachining and laser cutting techniques.

Abstract: A composite mirror and a method for making the mirror. The mirror has an aluminum reflective surface and coatings of aluminum oxide, chromium and gold deposited thereon, thus making the mirror highly reflective yet corrosion resistant. The method of making the mirror includes the steps of polishing the aluminum surface and depositing the coatings in sequence.