A module including a first semiconductor device, a second semiconductor device, a bridge support structure and a base substrate. The semiconductor devices each having first bonding pads having a first solder joined with the base substrate and the semiconductor devices each having second and third bonding pads joined to second and third bonding pads on the bridge support structure by a second solder and a third solder, respectively, on the second and third bonding pads; the semiconductor devices positioned adjacent to each other such that the bridge support structure joins to both of the semiconductor devices by the second and third solders wherein the third bonding pads are larger than the second bonding pads and the third bonding pads are at a larger pitch than the second bonding pads.

A module including a first semiconductor device, a second semiconductor device, a bridge support structure and a base substrate. The semiconductor devices each having first bonding pads having a first solder joined with the base substrate and the semiconductor devices each having second and third bonding pads joined to second and third bonding pads on the bridge support structure by a second solder and a third solder, respectively, on the second and third bonding pads; the semiconductor devices positioned adjacent to each other such that the bridge support structure joins to both of the semiconductor devices by the second and third solders wherein the third bonding pads are larger than the second bonding pads and the third bonding pads are at a larger pitch than the second bonding pads.

This disclosure is related to arranging micro devices in the donor substrate by either patterning or population so that there is no interfering with unwanted pads and the non-interfering area in the donor substrate is maximized. This enables to transfer the devices to receiver substrate with fewer steps.

An example of a method of micro-transfer printing comprises providing a micro-transfer printable component source wafer, providing a stamp comprising a body and spaced-apart posts, and providing a light source for controllably irradiating each of the posts with light through the body. Each of the posts is contacted to a component to adhere the component thereto. The stamp with the adhered components is removed from the component source wafer. The selected posts are irradiated through the body with the light to detach selected components adhered to selected posts from the selected posts, leaving non-selected components adhered to non-selected posts. In some embodiments, using the stamp, the selected components are adhered to a provided destination substrate. In some embodiments, the selected components are discarded. An example micro-transfer printing system comprises a stamp comprising a body and spaced-apart posts and a light source for selectively irradiating each of the posts with light.

Provided is a ultra-small light-emitting diode (LED) electrode assembly including a base substrate; an electrode line formed on the base substrate, and including a first electrode and a second electrode formed in a line shape to be interdigitated with each other while being spaced apart from each other; and at least one ultra-small LED device connected to the electrode line. A cross section of at least one of the first and second electrodes in a vertical direction has a height variation such that the first and second electrodes easily come in contact with the at least one ultra-small LED device.

Provided is a ultra-small light-emitting diode (LED) electrode assembly including a base substrate; an electrode line formed on the base substrate, and including a first electrode and a second electrode formed in a line shape to be interdigitated with each other while being spaced apart from each other; and at least one ultra-small LED device connected to the electrode line. A cross section of at least one of the first and second electrodes in a vertical direction has a height variation such that the first and second electrodes easily come in contact with the at least one ultra-small LED device.

Embodiments relate to using flux or underfill as a trapping layer for temporarily attaching light emitting diodes (LEDs) to a substrate and heating to simultaneously bond multiple LEDs onto the substrate. The flux or underfill may be selectively coated at the ends of electrodes of the LEDs prior to placing the LEDs on the substrate. Due to adhesive properties of the flux or underfill, multiple LEDs can be placed on and attached to the substrate prior to performing the bonding process. Once LEDs are placed on the substrate, the flux or underfill facilitates formation of metallic contacts between electrodes of the LED and contacts of the substrate during the bonding process. By using the flux or underfill, the formation of metallic contacts can be performed even without applying pressure.

A method of forming an electrical device is provided that includes forming microprocessor devices on a microprocessor die; forming memory devices on an memory device die; forming component devices on a component die; and forming a plurality of packing devices on a packaging die. Transferring a plurality of each of said microprocessor devices, memory devices, component devices and packaging components to a supporting substrate, wherein the packaging components electrically interconnect the memory devices, component devices and microprocessor devices in individualized groups. Sectioning the supporting substrate to provide said individualized groups of memory devices, component devices and microprocessor devices that are interconnected by a packaging component.

An apparatus for positioning micro-devices on a substrate includes one or more supports to hold a donor substrate and a destination substrate, an adhesive dispenser to deliver adhesive on micro-devices on the donor substrate, a transfer device including a transfer surface to transfer the micro-devices from the donor substrate to the destination substrate, and a controller. The controller is configured to operate the adhesive dispenser to selectively dispense the adhesive onto selected micro-devices on the donor substrate based on a desired spacing of the selected micro-devices on the destination substrate. The controller is configured to operate the transfer device such that the transfer surface engages the adhesive on the donor substrate to cause the selected micro-devices to adhere to the transfer surface and the transfer surface then transfers the selected micro-devices from the donor substrate to the destination substrate

A micro light-emitting device includes a support substrate, at least one micro light-emitting element, and a support structure. The support structure includes a bonding layer, an electrically conductive layer, and a protective insulation layer. The micro light-emitting element is supported by the support structure on the support substrate. The micro light-emitting element includes a light-emitting structure and first and second electrodes. First and second contact regions of the first electrode are respectively connected to a supporting post portion of the electrically conductive layer and a surrounding post portion of the protective insulation layer. A production method of the device and use of the element are also disclosed.