There is provided an electronic apparatus including: a heating section; a heat storage section; a detection section configured to detect a heat storage amount of the heat storage section; and a control section configured to control operation of the heating section, based on the heat storage amount detected by the detection section.

An integrated circuit assembly may be formed using a phase change material as an electromagnetic shield and as a heat dissipation mechanism for the integrated circuit assembly. In one embodiment, the integrated circuit assembly may comprise an integrated circuit package including a first substrate having a first surface and an opposing second surface, and at least one integrated circuit device having a first surface and an opposing second surface, wherein the at least one integrated circuit device is electrically attached by the first surface thereof to the first surface of the first substrate; and a phase change material formed on the integrated circuit package.

An integrated circuit structure may be formed using a phase change material to substantially fill at least one chamber within the integrated circuit assembly to increase thermal capacitance. The integrated circuit assembly may comprise a substrate, at least one integrated circuit device electrically attached to the substrate, a heat dissipation device, a thermal interface material between the integrated circuit device and the heat dissipation device, a chamber defined by the heat dissipation device, the substrate, and the integrated circuit device, and a phase change material within the chamber.

Encapsulated stress mitigation layers and assemblies having the same are disclosed. An assembly that includes a first substrate, a second substrate, an encapsulating layer disposed between the first and second substrates, and a stress mitigation layer disposed in the encapsulating layer such that the stress mitigation layer is encapsulated within the encapsulating layer. The stress mitigation layer has a lower melting temperature relative to a higher melting temperature of the encapsulating layer. The assembly includes an intermetallic compound layer disposed between the first substrate and the encapsulating layer such that the encapsulating layer is separated from the first substrate by the intermetallic compound layer. The stress mitigation layer melts into a liquid when the assembly operates at a temperature above the low melting temperature of the stress mitigation layer and the encapsulating layer maintains the liquid of the stress mitigation layer within the assembly.

A self-contained active thermal regulating device includes a flexible, deformable outer membrane; a liquid saturated foam core contained therein having a dimension substantially coincident with the outer membrane wherein the liquid is at least partially circulable throughout the foam core; and, a phase change material being in intimate contact with the circulable liquid. The circulation of the liquid is effective to transfer heat between the flexible, deformable outer membrane and the phase change material to cool (or heat) the device without use of external power and the saturated foam core in cooperation with the sealable flexible membrane providing a substantially uniform, thermal regulating medium and structural support such that the device is readily, uniformly deformable when a load is applied thereto.

A structure includes a thermal interface material, and a Perforated Foil Sheet (PFS) including through-openings therein, with a first portion of the PFS embedded in the thermal interface material. An upper layer of the thermal interface material is overlying the PFS, and a lower layer of thermal interface material is underlying the PFS. The thermal interface material fills through-openings in the PFS.

A cooling device includes a substrate defining a substrate upper surface, and a fin positioned on the substrate upper surface, the fin including a deformable encapsulating layer coupled to the substrate upper surface and defining an interior region, and a phase-change material encapsulated within the interior region, where the phase-change material changes from a first matter phase to a second matter phase at a boiling point of a working fluid positioned on the deformable encapsulating layer.

A heat dissipation structure comprises a flexible substrate, a graphite sheet, and a heat insulating material. The flexible substrate comprises a first surface and a second surface facing away from the first surface. The graphite sheet is connected to the second surface. At least one containing cavity is defined on an interface between the second surface and the graphite sheet. The heat insulating material is filled in the at least one containing cavity to form a heat insulating structure.

A heat dissipation apparatus applied to a terminal device includes a phase change material (PCM) and a heat transfer unit. The heat transfer unit is in contact with the PCM to conduct heat of the terminal device to the PCM. Because the PCM maintains a temperature substantially unchanged during a phase change, a temperature of the heat dissipation apparatus is not excessively high while heat is absorbed.

A method and apparatus for heat-dissipation a structure having a first and second surface. The first surface defines a heat absorbing surface having a plurality of cavities and a heat absorbing coating applied to the first surface and within the cavities. Additionally, a set of etchings can be provided on the first surface to increase absorption. The cavities can be pyramidal, hexagonal, or conical shapes, for example.