Methods for manufacturing a display device are provided. The methods include providing a plurality of light-emitting units and a substrate. The methods also include transferring the light-emitting units to a transfer head. The methods further include attaching at least one of the plurality of light-emitting units on the transfer head to the substrate by a bonding process, wherein the transfer head and the substrate satisfy the following equation during the bonding process:

Q|.sub.T1.sup.T2A(T)dT.sub.T1.sup.T3E(T)dT|<0.01, wherein A(T) is the coefficient of thermal expansion of the transfer head, E(T) is the coefficient of thermal expansion of the substrate, T1 is room temperature, T2 is the temperature of the transfer head, and T3 is the temperature of the substrate.

An electronic device and a method of making an electronic device. As non-limiting examples, various aspects of this disclosure provide methods of making an electronic device, and electronic devices made thereby, that comprise forming first and second encapsulating materials, followed by further processing and the removal of the entire second encapsulating material.

A package includes first package component and a second package component. The first package component includes a first electrical connector at a surface of the first package component, and a first solder region on a surface of the first electrical connector. The second package component includes a second electrical connector at a surface of the second package component, and a second solder region on a surface of the second electrical connector. A metal pin has a first end bonded to the first solder region, and a second end bonded to the second solder region.

An elastomeric interface layer (elayer) is formed over multiple light emitting diode (LED) dies by depositing photoresist materials across multiple LED dies, and using the LED dies as a photolithography mask to facilitate formation of the elayer on each LED die. The elayer facilitates adhesive attachment of each LED die with a pick and place head (PPH), allowing the LED dies to be picked up and placed onto a display substrate including control circuits for sub-pixels of an electronic display. In some embodiments, the LED dies are micro-LED (LED) dies.

A method of liquid assisted micro cold binding is provided. The method includes: forming a conductive pad on the substrate in which the conductive pad consists essentially of indium; forming a liquid layer on the conductive pad; placing a micro device having an electrode facing the conductive pad over the conductive pad such that the micro device is in contact with the liquid layer and is gripped by a capillary force produced by the liquid layer between the micro device and the conductive pad in which the electrode consists essentially of indium; and evaporating the liquid layer such that the electrode is bound to the conductive pad and is in electrical contact with the conductive pad.

A method for producing an illumination device may include providing a plurality of optoelectronic semi-conductor components that each have a semi-conductor layer sequence for generating radiation where the semiconductor components each have at least one contact surface on one side and are held by a common carrier. The method may further include electroplating each contact surface of the semi-conductor components using a solder material, applying the semi-conductor components having the solder material to a substrate, and melting and soldering the contact surfaces onto the surfaces.

A semiconductor device assembly that includes a substrate having a first side and a second side, the first side having at least one dummy pad and at least one electrical pad. The semiconductor device assembly includes a first semiconductor device having a first side and a second side and at least one electrical pillar extending from the second side. The electrical pillar is connected to the electrical pad via solder to form an electrical interconnect. The semiconductor device assembly includes at least one dummy pillar extending from the second side of the first semiconductor device and a liquid positioned between an end of the dummy pillar and the dummy pad. The surface tension of the liquid pulls the dummy pillar towards the dummy pad. The surface tension may reduce or minimize a warpage of the semiconductor device assembly and/or align the dummy pillar and the dummy pad.

An integrated circuit interconnects are described herein that are suitable for forming integrated circuit chip packages. In one example, an integrated circuit interconnect is embodied in a wafer that includes a substrate having a plurality of integrated circuit (IC) dice formed thereon. The plurality of IC dice include a first IC die having first solid state circuitry and a second IC die having second solid state circuitry. A first contact pad is disposed on the substrate and is coupled to the first solid state circuitry. A first solder ball is disposed on the first contact pad. The first solder ball has a substantially uniform oxide coating formed thereon.

In an embodiment, a device includes: a first reflective structure including first doped layers of a semiconductive material, alternating ones of the first doped layers being doped with a p-type dopant; a second reflective structure including second doped layers of the semiconductive material, alternating ones of the second doped layers being doped with a n-type dopant; an emitting semiconductor region disposed between the first reflective structure and the second reflective structure; a contact pad on the second reflective structure, a work function of the contact pad being less than a work function of the second reflective structure; a bonding layer on the contact pad, a work function of the bonding layer being greater than the work function of the second reflective structure; and a conductive connector on the bonding layer.

A stacked wafer assembly is made by forming a grid of grooves corresponding to projected dicing lines in a face side of each of two wafers, thereby forming demarcated areas on the face side of each of the two wafers. One of the wafers is installed with demarcated areas face upwardly, and thereafter liquid is supplied to the demarcated areas in a quantity just enough to stay on upper surfaces of the demarcated areas without overflowing. The other wafer is placed over the one wafer with demarcated areas of the other wafer facing the respective demarcated areas of the one wafer, thereby bringing respective central positions of the facing demarcated areas of the wafers into self-alignment with each other under the surface tension of the liquid sandwiched between the facing demarcated areas. The liquid is removed to bring the wafers into intimate contact with each other.