A thermal transistor is provided. The thermal transistor includes a metallic thermal conductor, a non-metallic thermal conductor, and a thermal resistance adjusting unit. The metallic thermal conductor and the non-metallic thermal conductor are contact with each other to form a thermal interface. The thermal resistance adjusting unit is configured to generate an bias voltage U.sub.12 between the metallic thermal conductor and the non-metallic thermal conductor.

A thermal switch having an on-state and an off-state is provided. First and second plates are composed from a thermally conductive material. The first and second plates are connected to form an internal cavity having a channel defining a gap between the first and second plate. The first reservoir is coupled to the channel and contains a thermally conductive liquid. The actuator is coupled to the first reservoir and the channel and is moveable between a first state and a second state corresponding to the on-state and the off-state of the thermal switch, respectively. Thermally conductive liquid is allowed to flow from the first reservoir to the channel when the actuator is in the first state and allowed to flow from the channel to the first reservoir when the actuator is in the second state.

A thermal transistor is provided. The thermal transistor includes a metallic thermal conductor, a non-metallic thermal conductor, and a thermal resistance adjusting unit. The metallic thermal conductor and the non-metallic thermal conductor are contact with each other to form a thermal interface. The thermal resistance adjusting unit is configured to generate an electric field at the thermal interface.

This disclosure provides a heat dissipation device configured to be in thermal contact with a heat source. The heat dissipation device includes a heat dissipation body and a cover plate. The heat dissipation body has at least one vertical channel. The heat dissipation body is configured to be in thermal contact with the heat source. The cover plate includes a first layer and a second layer that are stacked on each other. The first layer is stacked on the heat dissipation body and covers the at least one vertical channel. A thermal conductivity of the first layer is larger than a thermal conductivity of the second layer. The cover plate has at least one first through hole penetrating through the first layer and the second layer and connecting to the at least one vertical channel.

There is provided a heat-conductive flexible sheet that is formed of a non-silicone material and excellent in flexibility as well as durability such as heat-aging resistance, hydrothermal resistance, and thermal shock resistance, and a heat dissipation structure using the same, as well as a resin composition that exhibits excellent handleability in the kneading step in producing a heat-conductive sheet and can be suitably used as a binder material for a heat-conductive flexible sheet. A resin composition comprising a blocked urethane prepolymer, a predetermined epoxy compound, and a curing catalyst, the blocked urethane prepolymer being a reaction product of an aliphatic diisocyanate compound and a hydrogenated polybutadiene polyol having a hydroxy group at each of both ends, wherein the reaction product has at an end thereof an isocyanate group blocked with an aromatic hydroxy compound; a heat-conductive flexible sheet formed of a cured product of a mixed composition comprising the same and a heat-conductive inorganic filler; and a heat dissipation structure using the same.

A multilayer structure comprises a plurality of composite structures in a stacked configuration, each having a copper layer having a thickness of no larger than 25 m, and first and second graphene layers sandwiching the copper layer. The first graphene layer of a first composite structure among the plurality of composite structures directly contacts a second graphene layer of a second composite structure among the plurality of composite structures to form a graphene bi-layer structure. Either the first or second graphene layer of the graphene bi-layer structure comprises silver atoms, but not both. The silver atoms are ring-centered on graphene rings and delocalized inside the graphene rings.

A thermal switch having an on-state and an off-state is provided. First and second plates are composed from a thermally conductive material. The first and second plates are connected to form an internal cavity having a channel defining a gap between the first and second plate. The first reservoir is coupled to the channel and contains a thermally conductive liquid. The actuator is coupled to the first reservoir and the channel and is moveable between a first state and a second state corresponding to the on-state and the off-state of the thermal switch, respectively. Thermally conductive liquid is allowed to flow from the first reservoir to the channel when the actuator is in the first state and allowed to flow from the channel to the first reservoir when the actuator is in the second state.

A thermal management system for transferring heat from a heat load includes a composite structural member that supports a heat load source and a heat transfer member in thermal contact with the composite structural member, and in thermal contact with a heat sink. The system further includes at least one thermally-conductive first fastener that is in thermal contact with the heat transfer member, couples the heat load source to the composite structural member, and conducts heat from the heat load source into the heat transfer member. The heat transfer member conducts heat from the thermally-conductive first fastener to the heat sink.

An apparatus is provided which comprises: a die comprising an integrated circuit, a first material layer comprising a first metal, the first material layer on a surface of the die, and extending at least between opposite lateral sides of the die, a second material layer comprising a second metal over the first material layer, and a third material layer comprising silver particles and having a porosity greater than that of the second material layer, the third material layer between the first material layer and the second material layer. Other embodiments are also disclosed and claimed.

Transceiving unit with heat dissipation capabilities. The transceiving unit comprises a housing adapted to being inserted into a port of a hosting unit, the housing defining a top surface. The transceiving unit comprises a rear connector located on a back panel of the housing. The transceiving unit comprises at least one electronic component located inside the housing. The transceiving unit comprises an insert disposed along the top surface of the housing, the insert passively extracting heat generated by the at least one electronic component located inside the housing. Alternatively or complementarily to the insert, the transceiving unit comprises a heat sink integrated to a front panel of the housing for passively extracting heat generated by the at least one electronic component located inside the housing. In a particular aspect, the transceiving unit is a standardized hot-pluggable transceiving unit, the housing having standardized dimensions.