A light emitting diode (LED) includes a n-doped semiconductor material layer, a p-doped semiconductor material layer, an active region disposed between the n-doped semiconductor layer and the p-doped semiconductor layer, and a photonic crystal grating configured to increase the light extraction efficiency of the LED.

Disclosed herein is a method for manufacturing a semiconductor comprising mechanically connecting one or more separate semiconductor components to a common intermediate carrier, arranging the intermediate carrier with respect to a substrate so that, at least for a majority of the semiconductor components, at least one solder pad of a particular semiconductor component lies opposite a solder pad of the substrate associated therewith forming a solder joint, and connecting mutually assiocaited solder pads of the one or more semiconductor components and the substrate by melting and solidifying a solder material arranged between the mutually associated solder pads. A surface tension of the solder material between the mutually associated solder pads of the substrate and the one or more semiconductor components sets a predetermined position of the intermediate carrier relative to the substrate, in which the one or more semiconductor components assume a target position relative to the substrate.

An inorganic light emitting diode is disclosed. The inorganic light emitting diode includes a first semiconductor layer, a second semiconductor layer having a light emitting surface composed of four sides, an active layer disposed between the first semiconductor layer and the second semiconductor layer, a first electrode coupled to the first semiconductor layer, and a second electrode coupled to the second semiconductor layer, wherein the light emitting surface has a trapezoid shape in which two opposing sides are symmetric with respect to each other.

Embodiments disclosed herein include multi-die modules and methods of assembling multi-die modules. In an embodiment, a multi-die module comprises a first die. In an embodiment the first die comprises a first pedestal, a plateau around the first pedestal, and a stub extending up from the plateau. In an embodiment, the multi-die module further comprises a second die. In an embodiment, the second die comprises a second pedestal, where the second pedestal is attached to the first pedestal.

Techniques and mechanisms for mitigating stress on hybrid bonded interfaces in a multi-tier arrangement of integrated circuit (IC) dies. In an embodiment, first dies are bonded at a host die each via a respective one of first hybrid bond interfaces, wherein a second one or more dies are coupled to the host die each via a respective one of the first dies, and via a respective second hybrid bond interface. Stress at one of the hybrid bond interfaces is mitigated by properties of a first dielectric layer that extends to that hybrid bond interface. In another embodiment, stress at a given one of the hybrid bond interfaces is mitigated by properties of a dummy chip—or alternatively, properties of a patterned encapsulation structure—which is formed on the given hybrid bond interface.

A guide apparatus configured to transfer light-emitting devices in a liquid onto a substrate is provided. The guide apparatus includes a base configured to support the substrate; and a guide member configured to couple with the base to be seated on a mounting surface of the substrate in a state in which the substrate is supported on a surface of the base, wherein the guide member includes guide holes configured to respectively guide the light-emitting devices in the liquid to be disposed on the mounting surface of the substrate.

A method is provided for fabricating an encapsulated emissive element. Beginning with a growth substrate, a plurality of emissive elements is formed. The growth substrate top surface is conformally coated with an encapsulation material. The encapsulation material may be photoresist, a polymer, a light reflective material, or a light absorbing material. The encapsulant is patterned to form fluidic assembly keys having a profile differing from the emissive element profiles. In one aspect, prior to separating the emissive elements from the handling substrate, a fluidic assembly keel or post is formed on each emissive element bottom surface. In one variation, the emissive elements have a horizontal profile. The fluidic assembly key has horizontal profile differing from the emissive element horizontal profile useful in selectively depositing different types of emissive elements during fluidic assembly. In another aspect, the emissive elements and fluidic assembly keys have differing vertical profiles useful in preventing detrapment.

A method of mounting electronic components on one or more carrier bodies is disclosed. The method comprises providing a support body with at least one first alignment mark, mounting the one or more carrier bodies, each having at least one second alignment mark, on the support body by alignment between the at least one first alignment mark and the at least one second alignment mark. Thereafter, the method includes mounting the plurality of electronic components on a respective one of the one or more carrier bodies by alignment using the at least one second alignment mark.

Methods and systems for a semiconductor device package with a die to interposer wafer first bond are disclosed and may include bonding a plurality of semiconductor die comprising electronic devices to an interposer wafer, and applying an underfill material between the die and the interposer wafer. Methods and systems for a semiconductor device package with a die-to-packing substrate first bond are disclosed and may include bonding a first semiconductor die to a packaging substrate, applying an underfill material between the first semiconductor die and the packaging substrate, and bonding one or more additional die to the first semiconductor die. Methods and systems for a semiconductor device package with a die-to-die first bond are disclosed and may include bonding one or more semiconductor die comprising electronic devices to an interposer die.

A die attach system is provided. The die attach system includes a verification substrate configured to receive a plurality of die, the verification substrate including a plurality of substrate reference markers. The die attach system also includes an imaging system for determining an alignment of the plurality of die with the verification substrate by imaging each of the plurality of die with respective ones of the plurality of substrate reference markers.