A thermal radiation heat dissipation device includes a radiation heat transfer pile including a plurality of polar dielectric material units of high energy gap, the polar dielectric material units each including at least one light scattering unit and a thermal radiation unit. The light scattering unit interacts with solar radiation to generate scattering of light. The thermal radiation unit interacts with thermal radiation to increase strength of thermal radiation.

A power module includes a first shell, a second shell, a circuit board assembly, and a heat dissipation encapsulation. The second shell is closed relative to the first shell and forms an accommodating space together with the first shell. The circuit board assembly is disposed in the accommodating space, and includes a circuit board body, a plurality of power components disposed on the circuit board body, and a plurality of electrical connectors electrically connected to the circuit board body. The electrical connectors are exposed from the first shell. The heat dissipation encapsulation is filled in the accommodating space and covers the circuit board assembly.

An electronic assembly is provided. The electronic assembly includes a heat-spreader component and at least one spring. The electronic assembly further includes a thermal pad contacting the at least one spring, and at least one layer of polymer directly contacting at least one of an upper surface and a lower surface of the thermal pad. Further disclosed is a method of assembling the electronic assembly. The method includes adhering a heat-dissipating sheet on a surface of a metal heat-spreader component. The method also includes placing a thermal pad on at least one spring extending from the surface of the metal heat-spreader component, and placing at least one layer of polymer so as to directly contact at least one of an upper surface and a lower surface of the thermal pad.

The thermally conductive resin composition containing: 5 to 95 parts by weight of a copolymer (a) having a (meth)acrylic monomer unit A having an anionic group, a (meth)acrylic monomer unit B having a cationic group, and a silicone (meth)acrylic monomer unit C; 95 to 5 parts by weight of a silicone resin (b); and 500 to 3000 parts by weight of a thermally conductive filler (c) having a thermal conductivity of 10 W/mK or more, wherein a total content of the copolymer (a) and the silicone resin (b) is 100 parts by weight, and the silicone resin (b) includes a crosslinked silicone resin (b-1), wherein a content of the crosslinked silicone resin (b-1) is 5 to 100 mass % based on the total amount of the silicone resin (b).

The disclosed IC package may include (1) an IC die carrying electronic circuitry, (2) an encapsulation material that at least partially covers the IC die, where the encapsulation material defines a plurality of cavities in a top surface of the encapsulation material, (3) a plurality of microfans located in the plurality of cavities, and (4) a plurality of sensors embedded in the encapsulation material, where each sensor of the plurality of sensors produces a signal indicating a temperature at a location of the sensor. Various other IC packages, as well as associated cooling systems and methods, are also disclosed.

A high-resolution substrate having an area of at least 100 square centimeters and selected traces having a line/space dimension of 2 micrometers or less is employed to integrate multiple independently operable clusters of flip chip mounted components, thereby creating a circuit assembly. Each independently operable cluster of components preferably includes a power distribution chip, a test/monitor chip, and at least one redundant chip for each type of logic device and for each type of memory device. The components in at least one of the independently operable clusters of components may include the components provided in a commercially available chiplet assembly. An electronic system may comprise multiple substrates comprising independently operable clusters of components, plus a motherboard, a system controller, and a system input/output connector.

The disclosed IC package may include (1) an IC die carrying electronic circuitry, (2) an encapsulation material that at least partially covers the IC die, where the encapsulation material defines a plurality of cavities in a top surface of the encapsulation material, (3) a plurality of microfans located in the plurality of cavities, and (4) a plurality of sensors embedded in the encapsulation material, where each sensor of the plurality of sensors produces a signal indicating a temperature at a location of the sensor. Various other IC packages, as well as associated cooling systems and methods, are also disclosed.

A glass circuit assembly employing densely packed components is described. Air cooled computer systems employing densely packed circuit components are described. Relating to agile reconfigurable computer systems a high-resolution substrate having an area of at least 100 cm.sup.2 and selected traces having a line/space dimension of 2 micrometers or less is employed to integrate multiple independently operable clusters of flip chip mounted components in a circuit assembly. Switchable chips and redundant switchable chips may be included on each circuit assembly. Each independently operable cluster of components may include a power distribution chip, a test/monitor chip, and at least one redundant chip for each different logic device and for each different memory device. Chiplet components and combinations may be used to populate independently operable clusters of components. Agile reconfigurable systems are operable to adapt to changing workloads under direction of a system controller.

A high-resolution substrate having an area of at least 100 square centimeters and selected traces having a line/space dimension of 2 micrometers or less is employed to integrate multiple independently operable clusters of flip chip mounted components, thereby creating a circuit assembly. Each independently operable cluster of components preferably includes a power distribution chip, a test/monitor chip, and at least one redundant chip for each type of logic device and for each type of memory device. The components in at least one of the independently operable clusters of components may include the components provided in a commercially available chiplet assembly. An electronic system may comprise multiple substrates comprising independently operable clusters of components, plus a motherboard, a system controller, and a system input/output connector.

An information handling system includes a printed circuit board (PCB), a barrier frame, thermal potting material that fills the barrier frame, and a heat removing structure embedded into the thermal potting material. The barrier frame encloses a first device, and extends to also enclose a second location of the PCB. The thermal potting material surrounds the first device. The heat removing structure includes a first pad co-located with the first device, a second pad co-located with the second location, and a thermally conductive connection between the first pad and the second pad. The heat removing structure may remove heat generated by the first device to the second pad.