摘要:
Semiconductor integrated circuits (110) or assemblies are disposed at least partially in cavities between two interposers (120). Conductive vias (204M) pass through at least one of the interposers or at least through the interposer's substrate, and reach a semiconductor integrated circuit or an assembly. Other conductive vias (204M.1) pass at least partially through multiple interposers and are connected to conductive vias that reach, or are capacitively coupled to, a semiconductor IC or an assembly. Other features are also provided.
摘要:
Vias (holes) are formed in a wafer or a dielectric layer. A low viscosity conductive ink, containing microscopic metal particles, is deposited over the top surface of the wafer to cover the vias. An external force is applied to urge the ink into the vias, including an electrical force, a magnetic force, a centrifugal force, a vacuum, or a suction force for outgassing the air in the vias. Any remaining ink on the surface is removed by a squeegee, spinning, an air knife, or removal of an underlying photoresist layer. The ink in the vias is heated to evaporate the liquid and sinter the remaining metal particles to form a conductive path in the vias. The resulting wafer may be bonded to one or more other wafers and singulated to form a 3-D module.
摘要:
A multi-device package includes a substrate, at least two device regions, a first redistribution layer, an external chip, a plurality of first connectors and a conductive contact. The two device regions are formed from the substrate, and the substrate has a first surface and a second surface opposite to the first surface. The first redistribution layer is disposed on the first surface and electrically connected to the two device regions, and the external chip is disposed on the first redistribution layer. The first connectors are interposed between the first redistribution layer and the external chip to interconnect the first redistribution layer and the external chip, and the conductive contact is extended from the second surface to the first surface of the substrate to electrically connect the device region.
摘要:
A microelectronic device includes semiconductor device with a component at a front surface of the semiconductor device and a backside heat spreader layer on a back surface of the semiconductor device. The backside heat spreader layer is 100 nanometers to 3 microns thick, has an in-plane thermal conductivity of at least 150 watts/meter-° K, and an electrical resistivity less than 100 micro-ohm-centimeters.
摘要:
Through substrate via (TSuV) structures and method of making the same are disclosed herein. In embodiments, TSuV structures are metal filled selectively to avoid forming significant metal overburden on non-via surfaces of the substrate. In certain embodiments, post-fill metal removal/planarization operations are eliminated for reduced process complexity and manufacturing cost. In embodiments, selective metal fill entails selective electroless or electrolytic deposition. Both front side and back side selective deposition methods are described along with features of through substrate via structures made with such methods.
摘要:
Through substrate via (TSuV) structures and method of making the same are disclosed herein. In embodiments, TSuV structures are metal filled selectively to avoid forming significant metal overburden on non-via surfaces of the substrate. In certain embodiments, post-fill metal removal/planarization operations are eliminated for reduced process complexity and manufacturing cost. In embodiments, selective metal fill entails selective electroless or electrolytic deposition. Both front side and back side selective deposition methods are described along with features of through substrate via structures made with such methods.
摘要:
A semiconductor device includes a die, a substrate, a heat spreader and a plurality of signal interconnects extending from the die. The heat spreader has a base and a plurality of fins. The heat spreader is mounted on the substrate in such a way that the base of the head spreader is in thermal communication with the die. The fins protrude downwardly into the substrate conducting heat away from the die and into the substrate.
摘要:
Semiconductor integrated circuits (110) or assemblies are disposed at least partially in cavities between two interposers (120). Conductive vias (204M) pass through at least one of the interposers or at least through the interposer's substrate, and reach a semiconductor integrated circuit or an assembly. Other conductive vias (204M.1) pass at least partially through multiple interposers and are connected to conductive vias that reach, or are capacitively coupled to, a semiconductor IC or an assembly. Other features are also provided.
摘要:
Vias (holes) are formed in a wafer or a dielectric layer. A low viscosity conductive ink, containing microscopic metal particles, is deposited over the top surface of the wafer to cover the vias. An external force is applied to urge the ink into the vias, including an electrical force, a magnetic force, a centrifugal force, a vacuum, or a suction force for outgas sing the air in the vias. Any remaining ink on the surface is removed by a squeegee, spinning, an air knife, or removal of an underlying photoresist layer. The ink in the vias is heated to evaporate the liquid and sinter the remaining metal particles to form a conductive path in the vias. The resulting wafer may be bonded to one or more other wafers and singulated to form a 3-D module.
摘要:
Vias (holes) are formed in a wafer or a dielectric layer. A low viscosity conductive ink, containing microscopic metal particles, is deposited over the top surface of the wafer to cover the vias. An external force is applied to urge the ink into the vias, including an electrical force, a magnetic force, a centrifugal force, a vacuum, or a suction force for outgassing the air in the vias. Any remaining ink on the surface is removed by a squeegee, spinning, an air knife, or removal of an underlying photoresist layer. The ink in the vias is heated to evaporate the liquid and sinter the remaining metal particles to form a conductive path in the vias. The resulting wafer may be bonded to one or more other wafers and singulated to form a 3-D module.