Abstract: Systems and fabrication methods are disclosed for a heat spreader to cool a device. The heat spreader has first and second opposing proximal surfaces defining a chamber having a liquid therein; and one or more structures mounted in the chamber to induce a liquid flow pattern during a boiling of the liquid to distribute heat.

Abstract: Systems and fabrication methods are disclosed for a heat spreader to cool a device. The heat spreader has first and second opposing proximal surfaces defining a chamber having a liquid therein; and one or more structures mounted in the chamber to induce a liquid flow pattern during a boiling of the liquid to distribute heat.

Abstract: A cooling apparatus boiling and condensing liquid coolant has a vessel including a microporous surface enhancement coating applied on a thermally-conductive plate which is fully immersed under the liquid coolant in the vessel. The surface enhancement coating augments significantly a nucleate boiling heat transfer and critical heat flux when receiving heat from a heating object coupled to the thermally-conductive plate at a surface outside of the vessel. One embodiment of this invention including a vessel with a height/length dimension less than 300 mm, a microporous coating with nickel particles of 30-50 ?m in size bonded by a thermally-conductive binder, and water as the liquid coolant, without complicated radiator component, is used for cooling a heating electronics element.

Abstract: A microporous surface is created using particles of various sizes in conjunction with a thermally conductive binder. Advantages to a mixture batch type application of the coating include that it is an inexpensive and easy process which does not require extremely high operating temperatures. The disclosed coating technique is efficient for various types of working liquids simply by changing the size of metal particle sizes since different surface tension of liquids requires different size range of porous cavities to optimize boiling heat transfer performance. In one embodiment, the coating is applied to an electronic component surface.

Abstract: A thermal joint for facilitating heat transfer between two components is described. The thermal joint is formed from an alloy of at least two constituents. The alloy has a liquid temperature and a solid temperature. When the operating temperature falls between the liquid temperature and the solid temperature, the alloy has at least one liquid phase which is in substantial equilibrium with at least one solid phase. The thermal joint is used between a heat-generating component, such as a semiconducting device, and a heat-dissipating component, such as a heat sink. Such thermal joint substantially reduces the thermal resistance between the two components.

Abstract: A thermal joint for facilitating heat transfer between two components is described. The thermal joint is formed from an alloy of at least two constituents. The alloy has a liquid temperature and a solid temperature. When the operating temperature falls between the liquid temperature and the solid temperature, the alloy has at least one liquid phase which is in substantial equilibrium with at least one solid phase. The thermal joint is used between a heat-generating component, such as a semiconducting device, and a heat-dissipating component, such as a heat sink. Such thermal joint substantially reduces the thermal resistance between the two components.

Abstract: A coating composition comprising a glue, a particulate material and a solvent, which imparts a surface microstructure to a coated object (29) is disclosed. The particulate material projects above the glue line (28) of the coated object creating the microstructure which provides boiling heat transfer enhancement. A horizontally oriented, rectangular surface immersed in FC-72, indicates up to an 85% decrease in incipient superheat, a 70% to 80% reduction in nucleate boiling superheats, and a .about.109% increase in the critical heat flux (CHF), beyond that of the non-painted surface. The enhanced surface heat transfer coefficients are four to nine times higher than those from the reference surface. The coatings are applicable to electronic component surfaces. A coated silicon test chip tested at subcooled (45.degree. C. conditions using FC-72 had heat dissipation rates of .about.100 W/cm.sup.2 at junction temperatures of .about.85.degree. C., and the highest CHF observed was 159 W/cm.sup.