Systems and methods for utilizing the dead space around the periphery of a chip for sealing a direct liquid cooled module are disclosed. One of the functions of a direct liquid cooled module is to provide cooling liquid to components located on a chip. A groove member for receiving a sealing member may be applied to the top surface of the chip. The groove member may be directly deposited to the top surface or coupled thereto via an adhesive and/or epoxy. The groove member may be in the form of opposing sidewalls or a u-shaped structure each of which form a partial enclosure for receipt of the sealing member. The groove member may be located entirely within the dead space or at least partially within the dead space and partially within a central area in which the chip components are located. The sealing member may be an O-ring or a gasket.

A semiconductor chip includes semiconductor dice contained in a packaging apparatus including a cover and a plate, thereby forming a vapor chamber. The semiconductor dice and intermediate layers are alternately stacked. A capillary mechanism is provided on a horizontal internal face of the cover. Nets are provided on vertical internal faces of the cover, around the capillary mechanism. Each of the intermediate layers includes protuberances in contact with the nets. A channel is defined between any adjacent two of the protuberances. The channels travel past the intermediate layers. Coolant filled in the vapor chamber is turned into vapor after absorbing heat. The vapor ascends to the cover via the channels. The coolant is returned into liquid after transferring heat to the cover. The liquid descends to the plate. Thus, the coolant is circulated in the vapor chamber. Each of the intermediate layers includes a capillary structure to facilitate the circulation of the coolant.

A semiconductor package module includes a package, a conductive layer, and a heat dissipating module. The package includes a semiconductor die. The conductive layer is disposed over the package. The heat dissipating module is disposed over the conductive layer, and the package and the heat dissipating module prop against two opposite sides of the conductive layer, where the heat dissipating module is thermally coupled to and electrically isolated from the package through the conductive layer.

A two-phase immersion cooling system for integrated circuit assembly may be formed utilizing a heat dissipation device thermally coupled to at least one integrated circuit device, wherein the heat dissipation device may include a surface enhancement structure and a boiling enhancement material layer, such as a micro-porous material, on the surface enhancement structure.

A two-phase immersion cooling system for integrated circuit assembly may be formed utilizing a heat dissipation device thermally coupled to at least one integrated circuit device, wherein the heat dissipation device may include a surface enhancement structure and a boiling enhancement material layer, such as a micro-porous material, on the surface enhancement structure.

An electronic apparatus, a semiconductor package module and a method for manufacturing the semiconductor package module are provided. The semiconductor package module includes: an encapsulated structure, including a device die and an encapsulant laterally enclosing the device die; a package substrate, attached to a first side of the encapsulated structure; a composite thermal interfacial structure, disposed on a second side of the encapsulated structure, and including thermally conductive elements arranged side by side or stacked along a vertical direction; a ring structure, attached to the package substrate and laterally surrounding the encapsulated structure; and a heat spreader, attached to the second side of the encapsulated structure through the composite thermal interfacial structure, and supported by the ring structure.

An immersion heat dissipation structure having a macroscopic fin structure and an immersion heat dissipation structure having a fin structure are provided. The immersion heat dissipation structure having a macroscopic fin structure includes a surface having at least two contact angles. At least one part of the surface has one of the at least two contact angles between an immersion cooling liquid that is greater than 90 degrees, and at least another part of the surface has another one of the at least two contact angles between the immersion cooling liquid that is from 0 degrees to 90 degrees.

The present application discloses a rotary liquid distributor for a liquid-cooled tank, and a liquid-cooled tank. The rotary liquid distributor includes a liquid distribution cavity and a liquid distribution arm provided in the liquid distribution cavity. The liquid distribution cavity rotates around a central shaft thereof. A plurality of the liquid distribution arms are uniformly distributed in a circumferential direction of the liquid distribution cavity. That is, the liquid distribution arm rotates with the liquid distribution cavity. Then, a liquid distribution outlet is provided between a first end and a second end of the liquid distribution arm. The liquid distribution outlet is located on a side of the liquid distribution arm facing away from a rotating direction.

A vapor chamber includes a main body, a first vertical structure, and an enhanced boiling surface. The main body has a first surface and defines a first portion of an interior volume. The first vertical structure protrudes transverse to the main body and defines a second portion of the interior volume. The enhanced boiling surface is on at least a portion of the first vertical structure.

A single-phase immersion cooling system, comprising a fluid-tight containment vessel, dielectric thermally conductive fluid, at least a heat-generating electronic device, and heat exchanger system is provided. The heat exchanger system comprises a pump, heat exchanger, at least a first conduit, at least a second conduit, stand, and at least a propulsion-like apparatus. The at least a first and second conduits have first and second modifiable portions comprising first and second openings. The first and second openings are disposed near to greatest opposing ends of the dielectric thermally conductive fluid contained within the fluid-tight containment vessel generating at least a first flow channel for directing a first flow of the dielectric thermally conductive fluid. The at least a propulsion-like apparatus moves the dielectric thermally conductive fluid from one face to an opposite face in the same direction as the first flow, supplementing and enhancing circulation within the fluid-tight containment vessel.