A warpage control method includes measuring displacement in a vertical direction perpendicular to a front surface of a wafer and dividing the front surface of the wafer into a first stress region with a negative displacement value and a second stress region with a positive displacement value, to thereby derive a warpage model, defining a portion of a region, overlapping the first stress region, on the front surface of the wafer as a first compensation region based on the warpage model and defining a region, other than the first compensation region, on the front surface of the wafer as a second compensation region based on the warpage model, to thereby derive a stress compensation film pattern model, and forming a mask pattern in a region on a back surface of the wafer.

Alignment of a first micro-electronic component to a receiving surface of a second micro-electronic component is realized by a capillary force-induced self-alignment, combined with an electrostatic alignment. The latter is accomplished by providing at least one first electrical conductor line along the periphery of the first component, and at least one second electrical conductor along the periphery of the location on the receiving surface of the second component onto which the component is to be placed. The contact areas surrounded by the conductor lines are covered with a wetting layer. The electrical conductor lines may be embedded in a strip of anti-wetting material that runs along the peripheries to create a wettability contrast. The wettability contrast helps to maintain a drop of alignment liquid between the contact areas so as to obtain self-alignment by capillary force. By applying appropriate charges on the conductor lines, electrostatic self-alignment is realized, which improves the alignment obtained through capillary force and maintains the alignment during evaporation of the liquid.

Technologies are generally described related to three-dimensional integration of integrated circuits (ICs) with spacing for heat dissipation. According to some examples, a self-aligned silicide may be formed in a temporary silicon layer and removed subsequent to bonding of the wafers to achieve improved contact between the combined ICs and enhanced heat dissipation through added spacing between the ICs.

Post-processing steps for integrating of micro devices into system (receiver) substrate or improving the performance of the micro devices after transfer. Post processing steps for additional structures such as reflective layers, fillers, black matrix or other layers may be used to improve the out coupling or confining of the generated LED light. Dielectric and metallic layers may be used to integrate an electro-optical thin film device into the system substrate with transferred micro devices. Color conversion layers may be integrated into the system substrate to create different outputs from the micro devices.

This disclosure is related to post processing steps for integrating of micro devices into system (receiver) substrate or improving the performance of the micro devices after transfer. Post processing steps for additional structure such as reflective layers, fillers, black matrix or other layers may be used to improve the out coupling or confining of the generated LED light. In another example, dielectric and metallic layers may be used to integrate an electro-optical thin film device into the system substrate with the transferred micro devices. In another example, color conversion layers are integrated into the system substrate to create different output from the micro devices.

Post-processing steps for integrating of micro devices into system (receiver) substrate or improving the performance of the micro devices after transfer. Post processing steps for additional structures such as reflective layers, fillers, black matrix or other layers may be used to improve the out coupling or confining of the generated LED light. Dielectric and metallic layers may be used to integrate an electro-optical thin film device into the system substrate with transferred micro devices. Color conversion layers may be integrated into the system substrate to create different outputs from the micro devices.

This disclosure is related to post processing steps for integrating of micro devices into system (receiver) substrate or improving the performance of the micro devices after transfer. Post processing steps for additional structure such as reflective layers, fillers, black matrix or other layers may be used to improve the out coupling or confining of the generated LED light. In another example, dielectric and metallic layers may be used to integrate an electro-optical thin film device into the system substrate with the transferred micro devices. In another example, color conversion layers are integrated into the system substrate to create different output from the micro devices.

Microelectronic assemblies fabricated using hybrid manufacturing with modified via-last process are disclosed. The fabrication approach is based on using hybrid manufacturing to bond first and second IC structures originally provided on different dies but filling at least portions of vias that are supposed to couple across a bonding interface between the first and second IC structures with electrically conductive materials after the IC structures have been bonded. A resulting microelectronic assembly that includes the first and second IC structures bonded together may have vias extending through all of the first IC structure and into the second IC structure, thus providing electrical coupling between one or more components of the first IC structure and those of the second IC structure, where an electrically conductive material in the individual vias is continuous through the first IC structure and at least a portion of the second IC structure.

Methods of bonding one or more dies to a substrate are provided herein. In some embodiments, a method of bonding one or more dies to a substrate includes: applying a material coating on the one or more dies or the substrate; placing the one or more dies on the substrate so that the one or more dies temporarily adhere to the substrate via surface tension or tackiness of the material coating; inspecting each of the one or more dies that are placed on the substrate for defects; and removing any of the one or more dies that are found to have defects.

A semiconductor device includes a lower structure and an upper structure on the lower structure. The lower structure includes a first semiconductor substrate, a first pad and a first dielectric layer. The first dielectric layer surrounds the first pad and exposes a top surface of the first pad. The upper structure includes a second semiconductor substrate, a second pad and a second dielectric layer. The second dielectric layer surrounds the second pad and exposes a bottom surface of the second pad. The first pad and the second pad are bonded to each other across an interfacial layer to couple the upper and lower structures to each other. The first and second pads and the interfacial layer include a same metallic material. The first and second pads have a substantially same average grain size and the interfacial layer has a different average grain size than the first and second pads.