A method utilized at a sintered metal layer bonding a semiconductor element and a support substrate together suppresses cracks appearing in the sintered metal layer, and damage to the semiconductor element. A semiconductor device includes a support substrate, a semiconductor element, and a sintered metal layer bonding the support substrate and the semiconductor element. The sintered metal layer has a low porosity region disposed inward of an outer edge of the semiconductor element with the sintered metal layer bonded to the semiconductor element. The region is lower in porosity than the remaining sintered metal layer, and is formed as a wall-shaped structural body having an elongated string and extending from an upper surface to a lower surface of the sintered metal layer. The low porosity region is disposed to surround a region immediately below a center of the semiconductor element along the outer edge of the semiconductor element.

A metal sintered bonding body bonds a substrate and a die. In the metal sintered bonding body, at least a center part and corner part of a rectangular region where the metal sintered bonding body faces the die have a low-porosity region whose porosity is lower than an average porosity of the rectangular region. The low-porosity region is located within a strip-shaped region whose central lines are diagonal lines of the rectangular region.

A method for producing a component bonded to a solder preform, comprising the following steps: (1) providing a component having at least one contact surface, and a free solder preform, (2) producing an assembly of the component and the solder preform, which is not yet bonded to said component, by bringing a contact surface, or the sole contact surface, of the component into contact with a contact surface of the free solder preform, and (3) forming the component bonded to the solder preform by hot pressing the assembly produced in step (2) at a temperature that is 10 to 40% lower than the melting temperature of the soldering metal of the solder preform, expressed in ° C., and with a combination of pressing force and pressing duration that will effect a reduction of 10% in the original thickness of the originally free solder preform.

A display module and a manufacturing method thereof are provided. The manufacturing method may include forming an epitaxial film comprising a light emitting layer, a first type semiconductor layer, and a second type semiconductor layer, attaching the epitaxial film to an intermediate substrate comprising a conductive material, patterning the epitaxial film to form a light emitting diode (LED) and coupling the LED to a driving circuit layer through the conductive material.

A method of manufacturing a display device including the steps of providing a lower substrate having a display area and a pad area, forming a display structure in the display area of the lower substrate, forming pad electrodes in the pad area of the lower substrate to be spaced apart from each other in a first direction parallel to a top surface of the lower substrate, forming an upper substrate on the display structure to face the lower substrate in the display area, forming a conductive film member including a non-cured resin layer and conductive balls arranged in a lattice shape on the pad electrodes, the non-cured resin layer overlapping the pad electrodes, and forming a film package on the non-cured resin layer, the film package including bump electrodes overlapping the pad electrodes.

A method of forming a bonding assembly that includes positioning a plurality of polymer spheres against an opal structure and placing a substrate against a second major surface of the opal structure. The opal structure includes the first major surface and the second major surface with a plurality of voids defined therebetween. The plurality of polymer spheres encapsulates a solder material disposed therein and contacts the first major surface of the opal structure. The method includes depositing a material within the voids of the opal structure and removing the opal structure to form an inverse opal structure between the first and second major surfaces. The method further includes removing the plurality of polymer spheres to expose the solder material encapsulated therein and placing a semiconductor device onto the inverse opal structure in contact with the solder material.

A method of forming a bonding assembly that includes positioning a plurality of polymer spheres against an opal structure and placing a substrate against a second major surface of the opal structure. The opal structure includes the first major surface and the second major surface with a plurality of voids defined therebetween. The plurality of polymer spheres encapsulates a solder material disposed therein and contacts the first major surface of the opal structure. The method includes depositing a material within the voids of the opal structure and removing the opal structure to form an inverse opal structure between the first and second major surfaces. The method further includes removing the plurality of polymer spheres to expose the solder material encapsulated therein and placing a semiconductor device onto the inverse opal structure in contact with the solder material.

A display device including a lower substrate having a display area and a pad area, a display structure disposed in the display area of the lower substrate, an upper substrate disposed on the display structure in the display area, and facing the lower substrate, pad electrodes disposed in the pad area of the lower substrate and spaced apart from each other in a first direction parallel to a top surface of the lower substrate, a conductive film member including conductive balls disposed on the pad electrodes and having a first area overlapping the pad electrodes and a second area not overlapping the pad electrodes, and a film package disposed on the conductive film member and including bump electrodes overlapping the first area of the conductive film member, in which the shape of the conductive balls disposed in the first area is different from those disposed in the second area.

Methods for forming bonded assemblies using metal inverse opal and cap structures are disclosed. In one embodiment, a method for forming a bonded assembly includes positioning a substrate against a polymer support that is porous, depositing a metal onto and within the polymer support, disposing a cap layer to the polymer support opposite of the substrate to form a bottom electrode, and removing the polymer support from between the substrate and the cap layer to form a metal inverse opal structure disposed therebetween.

Methods for forming bonded assemblies using metal inverse opal and cap structures are disclosed. In one embodiment, a method for forming a bonded assembly includes positioning a substrate against a polymer support that is porous, depositing a metal onto and within the polymer support, disposing a cap layer to the polymer support opposite of the substrate to form a bottom electrode, and removing the polymer support from between the substrate and the cap layer to form a metal inverse opal structure disposed therebetween.