Abstract: A gas-expansion cooler assembly has an expansion structure with an expansion orifice and an expansion reservoir in fluid-flow communication with an expansion-orifice outlet. A heat exchanger has a heat-exchanger inlet, and a heat-exchanger outlet in fluid-flow communication with the expansion-orifice inlet. The heat exchanger includes at least two heat-exchanger plates stacked in a facing relationship along an assembly axis. Each heat-exchanger plate includes an in-plane channel lying substantially in a plane perpendicular to the assembly axis. The in-plane channels of the adjacent heat-exchanger plates are in fluid-flow communication with each other and with the expansion-orifice inlet to form a continuous high-pressure fluid-flow path from the heat-exchanger inlet to the expansion-orifice inlet. The heat exchanger further includes an axial channel extending parallel to the assembly axis.

Abstract: A gas-expansion cooler assembly has an expansion structure with an expansion orifice and an expansion reservoir in fluid-flow communication with an expansion-orifice outlet. A heat exchanger has a heat-exchanger inlet, and a heat-exchanger outlet in fluid-flow communication with the expansion-orifice inlet. The heat exchanger includes at least two heat-exchanger plates stacked in a facing relationship along an assembly axis. Each heat-exchanger plate includes an in-plane channel lying substantially in a plane perpendicular to the assembly axis. The in-plane channels of the adjacent heat-exchanger plates are in fluid-flow communication with each other and with the expansion-orifice inlet to form a continuous high-pressure fluid-flow path from the heat-exchanger inlet to the expansion-orifice inlet. The heat exchanger further includes an axial channel extending parallel to the assembly axis.

Abstract: A microelectronic system includes a substrate that is preferably silicon and a microelectronic device supported on the substrate. The microelectronic device may be a light sensor that include a readout integrated circuit formed in the silicon substrate, and a light detector supported on and electrically interconnected with the readout integrated circuit. A cryocooler formed in and integral with the substrate includes a gas inflow channel formed in the substrate, an expansion nozzle formed in the substrate and receiving a gas flow from the gas inflow channel, and a gas outflow channel that receives the gas flow from the outlet of the expansion nozzle. The gas inflow channel and the gas outflow channel may be countercurrent spirals.

Abstract: A microelectronic system includes a substrate that is preferably silicon and a microelectronic device supported on the substrate. The microelectronic device may be a light sensor that include a readout integrated circuit formed in the silicon substrate, and a light detector supported on and electrically interconnected with the readout integrated circuit. A cryocooler formed in and integral with the substrate includes a gas inflow channel formed in the substrate, an expansion nozzle formed in the substrate and receiving a gas flow from the gas inflow channel, and a gas outflow channel that receives the gas flow from the outlet of the expansion nozzle. The gas inflow channel and the gas outflow channel may be countercurrent spirals.