As a result of miniaturization of a pixel region associated with an improvement in definition and an increase in a substrate size associated with an increase in area, defects due to precision, bending, and the like of a mask used at the lime of evaporation have become issues. A partition including portions with different thicknesses over a pixel electrode (also referred to as a first electrode) in a display region and in the vicinity of a pixel electrode layer is formed, without increasing the number of steps, by using a photomask or a reticle provided with an auxiliary pattern having a light intensity reduction function made of a diffraction grating pattern or a semi-transmissive film.

The present invention relates to a semiconductor light-emitting device having a two-stage photonic crystal pattern formed thereon, and to a method for manufacturing same. According to the present invention, a second photonic crystal pattern is formed inside a first photonic crystal pattern formed on a semiconductor layer or transparent electrode layer, in order to improve light extraction efficiency. Also, according to the present invention, in order to form a second fine nanoscale photonic crystal pattern in the first photonic crystal pattern, a nanosphere lithography process employing polymer beads is used, and a trapping layer made of a thermoplastic resin was used to conveniently form polymer beads in a single layer so as to eliminate the inconvenience of having to calculate and change process variables according to polymer bead sizes in traditional nanosphere lithography processes.

The present invention relates to a semiconductor light-emitting device having a two-stage photonic crystal pattern formed thereon, and to a method for manufacturing same. According to the present invention, a second photonic crystal pattern is formed inside a first photonic crystal pattern formed on a semiconductor layer or transparent electrode layer, in order to improve light extraction efficiency. Also, according to the present invention, in order to form a second fine nanoscale photonic crystal pattern in the first photonic crystal pattern, a nanosphere lithography process employing polymer beads is used, and a trapping layer made of a thermoplastic resin was used to conveniently form polymer beads in a single layer so as to eliminate the inconvenience of having to calculate and change process variables according to polymer bead sizes in traditional nanosphere lithography processes.

A light emitting device of an embodiment includes first and second light transmissive support bodies, and a light emitting diode is disposed between the bases. The light emitting diode includes a first semiconductor layer provided on a first surface (area S.sub.1) of a substrate, a light emitting layer (area S.sub.2), and a second semiconductor layer. A first electrode in a pad shape is formed on the second semiconductor layer. The light emitting diode has a shape satisfying a relation of “1≦S.sub.1/S.sub.2≦−(3.46/H)+2.73”, where H is a distance from the first surface of the substrate to a surface of the first electrode.

A light emitting device of an embodiment includes first and second light transmissive support bodies, and a light emitting diode is disposed between the bases. The light emitting diode includes a first semiconductor layer provided on a first surface (area S.sub.1) of a substrate, a light emitting layer (area S.sub.2), and a second semiconductor layer. A first electrode in a pad shape is formed on the second semiconductor layer. The light emitting diode has a shape satisfying a relation of “1≦S.sub.1/S.sub.2≦−(3.46/H)+2.73”, where H is a distance from the first surface of the substrate to a surface of the first electrode.

A color stacked light emitting diode (LED) pixel is disclosed. The color stacked LED includes an LED pixel structure body, a base LED disposed on at least a portion of the LED pixel structure body, an intermediate LED disposed on the base LED, and a top LED disposed on the intermediate LED. The stacked LED may be an overlapping or a non-overlapping LED pixel. The LED pixel structure body may be a fin body or a nanowire body.

A semiconductor device disclosed in an embodiment comprises: a light emitting unit comprising a light emitting structure layer which has a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer; and a sensor unit disposed on the light emitting unit, wherein the sensor unit comprises: a sensing material changing in resistance with light emitted by the light emitting unit; a first sensor electrode comprising a first pad portion and a first extension part extending from the first pad portion and contacting the sensing material; and a second sensor electrode comprising a first pad portion and a second extension part extending toward the first extension part from the second pad portion and contacting the sensing material. The sensor unit senses an external gas in response to the light generated from the light emitting unit.

A semiconductor device disclosed in an embodiment comprises: a light emitting unit comprising a light emitting structure layer which has a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer; and a sensor unit disposed on the light emitting unit, wherein the sensor unit comprises: a sensing material changing in resistance with light emitted by the light emitting unit; a first sensor electrode comprising a first pad portion and a first extension part extending from the first pad portion and contacting the sensing material; and a second sensor electrode comprising a first pad portion and a second extension part extending toward the first extension part from the second pad portion and contacting the sensing material. The sensor unit senses an external gas in response to the light generated from the light emitting unit.

Described herein are solid-state devices based on graphene in a Field Effect Transistor (FET) structure that emits high frequency Electromagnetic (EM) radiation using one or more DC electric fields and periodic magnetic arrays or periodic nanostructures. A number of devices are described that are capable of generating and emitting electromagnetic radiation.

Described herein are solid-state devices based on graphene in a Field Effect Transistor (FET) structure that emits high frequency Electromagnetic (EM) radiation using one or more DC electric fields and periodic magnetic arrays or periodic nanostructures. A number of devices are described that are capable of generating and emitting electromagnetic radiation.