A method of manufacturing a multi-layer wafer is provided. At least one stress compensating polymer layer is applied to at least one of two heterogeneous wafers. The stress compensating polymer layer is low temperature bonded to the other of the two heterogeneous wafers to form a multi-layer wafer pair. Channels are created between die on at least one of the two heterogeneous wafers. The channels are back filled with one of oxide or polymer to create a channel oxide deposition.

A semiconductor device includes: a redistribution line provided on a main face of a first semiconductor chip; an insulating film covering a front face of the redistribution line, the insulating film including a first opening and a second opening that each partially expose the redistribution line; a first electrode provided on the insulating film, and is connected to the redistribution line at the first opening, the first electrode formed of the same material as the redistribution line; and a second electrode provided on the insulating film, and is connected to the redistribution line at the second opening, the second electrode formed of a material that differ from a material of the first electrode.

A cell of fluidic assembly of microchips on a substrate, including: a base having its upper surface intended to receive the substrate; a body laterally delimiting a fluidic chamber above the substrate; and a cover closing the fluidic chamber from its upper surface, wherein the body comprises first and second nozzles respectively emerging onto opposite first and second lateral edges of the fluidic chamber, each of the first and second nozzles being adapted to injecting and/or sucking in a liquid suspension of microchips into and/or from the fluidic chamber, in a direction parallel to the mean plane of the substrate.

A display device includes a substrate including an active area having pixels and a non-active area including a pad region. A pad electrode is disposed in the pad region and includes a first pad electrode and a second pad electrode disposed on the first pad electrode. A first insulating pattern is interposed between the first and second pad electrodes. In a plan view, the first insulating pattern is positioned inside the first pad electrode, and a portion of the second pad electrode overlapping the first insulating pattern protrudes further from the substrate in a thickness direction than a portion of the second pad electrode not overlapping the first insulating pattern. The second pad electrode directly contacts a portion of the upper surface of the first pad electrode. In a plan view, an area of the second pad electrode is greater than an area of the first pad electrode.

A multi-layer wafer and method of manufacturing such wafer are provided. The method includes applying at least one stress compensating polymer layer to at least one of two heterogeneous wafers and low temperature bonding the two heterogeneous wafers to bond the stress compensating polymer layer to the other of the two heterogeneous wafers to form a multi-layer wafer pair. The multi-layer wafer comprises two heterogeneous wafers, at least one of the heterogeneous wafers having a stress compensating polymer layer. The two heterogeneous wafers are low temperature bonded together to bond the stress compensating polymer layer to the other of the two heterogeneous wafers.

A method for fabricating a micro-LED module is disclosed. The method includes: preparing a micro-LED including a plurality of electrode pads and a plurality of LED cells; preparing a submount substrate including a plurality of electrodes corresponding to the plurality of electrode pads; and flip-bonding the micro-LED to the submount substrate through a plurality of solders located between the plurality of electrode pads and the plurality of electrodes. The flip-bonding includes heating the plurality of solders by a laser.

A method of manufacturing a multi-layer wafer is provided. The method comprises applying at least one stress compensating polymer layer to at least one of two heterogeneous wafers and low temperature bonding the two heterogeneous wafers to bond the stress compensating polymer layer to the other of the two heterogeneous wafers to form a multi-layer wafer pair. The multi-layer wafer comprises two heterogeneous wafers, at least one of the heterogeneous wafers having a stress compensating polymer layer. The two heterogeneous wafers are low temperature bonded together to bond the stress compensating polymer layer to the other of the two heterogeneous wafers.

A method for fabricating a micro-LED module is disclosed. The method includes: preparing a micro-LED including a plurality of electrode pads and a plurality of LED cells; preparing a submount substrate including a plurality of electrodes corresponding to the plurality of electrode pads; and flip-bonding the micro-LED to the submount substrate through a plurality of solders located between the plurality of electrode pads and the plurality of electrodes. The flip-bonding includes heating the plurality of solders by a laser.

A method includes performing a first strike process to strike a metal bump of a first package component against a metal pad of a second package component. A first one of the metal bump and the metal pad includes copper. A second one of the metal bump and the metal pad includes aluminum. The method further includes performing a second strike process to strike the metal bump against the metal pad. An annealing is performed to bond the metal bump on the metal pad.

An embodiment of the invention may include a semiconductor structure, and method of forming the semiconductor structure. The semiconductor structure may include a first set of pillars located on a first substrate. The semiconductor structure may include a second set of pillars located on a second substrate. The semiconductor structure may include a joining layer connecting the first pillar to the second pillar. The semiconductor structure may include an underfill layer located between the first and second substrate.