A method includes forming a stack of semiconductor die. The stack includes a first semiconductor die, a second semiconductor die and a third semiconductor die. The first semiconductor die is stacked above the second semiconductor die and the third semiconductor die is stacked above the first semiconductor die. A first optical transmitter and a first optical receiver are provided in the first semiconductor die, a second optical transmitter is provided in the second semiconductor die, and a second optical receiver is provided in the third semiconductor die. A first optical signal is transmitted from the first optical transmitter in the first semiconductor die to the second optical receiver in the third semiconductor die. A second optical signal is transmitted from the second optical transmitter in the second semiconductor die to the first optical receiver in the first semiconductor die.

A temporary chip assembly, a display panel, and manufacturing methods of the temporary chip assembly and the display panel are provided. In the display panel, welding points between a micro light-emitting chip and corresponding bonding pads on a display backboard are covered with pyrolytic adhesive to block water and oxygen, thereby slowing down or avoiding the oxidation of the welding points.

This application discloses a board, an electronic device, and a manufacturing method, and pertains to the field of bare die package technologies. The board includes a PCB assembly, a bare die, a reinforcing frame, a heat sink, and fasteners. Both the bare die and the reinforcing frame are located on a surface of the PCB assembly, the bare die is located in the reinforcing frame, and the reinforcing frame is fixedly connected to the PCB assembly by using the fastener. The heat sink is located on a surface of the bare die that is away from the PCB assembly, and the heat sink is fixedly connected to the reinforcing frame by using the fastener.

A dot matrix light-emitting diode (LED) backlighting light source for a wafer-level microdisplay includes a substrate and a bonding layer, multiple LEDs arranged at intervals, a first electrode assembly, and a second electrode assembly sequentially formed on a top surface of the substrate. The first electrode assembly and the second electrode assembly are connected in series to the multiple LEDs to constitute a dot matrix LED light source, which allows to be directly packaged and assembled in a microdisplay in production and is advantageous in reduced size and lower production.

A stacked semiconductor device encompasses a mother-plate having a mounting-main surface and a bottom-main surface, an onboard-element having a connection face facing to the mounting-main surface, a parent bump provided on the mother-plate, having a mother-site wall made of a layer of conductor, mother-site wall is perpendicular to the mounting-main surface, and a repair bump provided on the onboard-element at a side of the connection face, having a repair-site wall made of a layer of conductor having different hardness from the mother-site wall, the repair-site wall is perpendicular to the connection face, configure to bite each other with the parent bump at an intersection between the mother-site wall and the repair-site wall conductor.

A stacked semiconductor device encompasses a mother-plate having a mounting-main surface and a bottom-main surface, an onboard-element having a connection face facing to the mounting-main surface, a parent bump provided on the mother-plate, having a mother-site wall made of a layer of conductor, mother-site wall is perpendicular to the mounting-main surface, and a repair bump provided on the onboard-element at a side of the connection face, having a repair-site wall made of a layer of conductor having different hardness from the mother-site wall, the repair-site wall is perpendicular to the connection face, configure to bite each other with the parent bump at an intersection between the mother-site wall and the repair-site wall conductor.

A method of manufacturing a multi-layer wafer is provided. Under bump metallization (UMB) pads are created on each of two heterogeneous wafers. A conductive means is applied above the UMB pads on at least one of the two heterogeneous wafers. The two heterogeneous wafers are low temperature bonded to adhere the UMB pads together via the conductive means. At least one stress compensating polymer layer may be applied to at least one of two heterogeneous wafers. The stress compensating polymer layer has a polymer composition of a molecular weight polymethylmethacrylate polymer at a level of 10-50% with added liquid multifunctional acrylates forming the remaining 50-90% of the polymer composition.

Semiconductor device assemblies with solderless interconnects, and associated systems and methods are disclosed. In one embodiment, a semiconductor device assembly includes a first conductive pillar extending from a semiconductor die and a second conductive pillar extending from a substrate. The first conductive pillar may be connected to the second conductive pillar via an intermediary conductive structure formed between the first and second conductive pillars using an electroless plating solution injected therebetween. The first and second conductive pillars and the intermediary conductive structure may include copper as a common primary component, exclusive of an intermetallic compound (IMC) of a soldering process. A first sidewall surface of the first conductive pillar may be misaligned with respect to a corresponding second sidewall surface of the second conductive pillar. Such interconnects formed without IMC may improve electrical and metallurgical characteristics of the interconnects for the semiconductor device assemblies.

Semiconductor device assemblies with solderless interconnects, and associated systems and methods are disclosed. In one embodiment, a semiconductor device assembly includes a first conductive pillar extending from a semiconductor die and a second conductive pillar extending from a substrate. The first conductive pillar may be connected to the second conductive pillar via an intermediary conductive structure formed between the first and second conductive pillars using an electroless plating solution injected therebetween. The first and second conductive pillars and the intermediary conductive structure may include copper as a common primary component, exclusive of an intermetallic compound (IMC) of a soldering process. A first sidewall surface of the first conductive pillar may be misaligned with respect to a corresponding second sidewall surface of the second conductive pillar. Such interconnects formed without IMC may improve electrical and metallurgical characteristics of the interconnects for the semiconductor device assemblies.

Structures and methods are disclosed for fabricating optoelectronic solid state array devices. In one case a backplane and array of micro devices is aligned and connected through bumps.