A light emitting diode device has a bulk gallium and nitrogen containing substrate with an active region. The device has a lateral dimension and a thick vertical dimension such that the geometric aspect ratio forms a volumetric diode that delivers a nearly uniform current density across the range of the lateral dimension.

Embodiments relate to a light emitting device, a light emitting device package, and a lighting system comprising the same. The light emitting device according to embodiments may comprise: a first conductivity-type semiconductor layer; an active layer on the first conductivity-type semiconductor layer; an electron blocking layer on the active layer; and a second conductivity-type semiconductor layer on the electron blocking layer. The electron blocking layer may comprise an In.sub.xAl.sub.yGa.sub.1-x-yN based superlattice layer (wherein 0≦x≦1, 0≦y≦1).

A semiconductor light-emitting device comprises an epitaxial structure comprising an main light-extraction surface, a lower surface opposite to the main light-extraction surface, a side surface connecting the main light-extraction surface and the lower surface, a first portion and a second portion between the main light-extraction surface and the first portion, wherein a concentration of a doping material in the second portion is higher than that of the doping material in the first portion and, in a cross-sectional view, the second portion comprises a first width near the main light-extraction surface and second width near the lower surface, and the first width is smaller than the second width.

A semiconductor light-emitting device comprises an epitaxial structure comprising an main light-extraction surface, a lower surface opposite to the main light-extraction surface, a side surface connecting the main light-extraction surface and the lower surface, a first portion and a second portion between the main light-extraction surface and the first portion, wherein a concentration of a doping material in the second portion is higher than that of the doping material in the first portion and, in a cross-sectional view, the second portion comprises a first width near the main light-extraction surface and second width near the lower surface, and the first width is smaller than the second width.

A semiconductor light-emitting device includes a semiconductor stack including a first semiconductor layer and a second semiconductor layer; a first reflective layer formed on the first semiconductor layer and including a plurality of vias; a plurality of contact structures respectively filled in the vias and electrically connected to the first semiconductor layer; a second reflective layer including metal material formed on the first reflective layer and contacting the contact structures; a plurality of conductive vias surrounded by the semiconductor stack; a connecting layer formed in the conductive vias and electrically connected to the second semiconductor layer; a first pad portion electrically connected to the second semiconductor layer; and a second pad portion electrically connected to the first semiconductor layer, wherein a shortest distance between two of the conductive vias is larger than a shortest distance between the first pad portion and the second pad portion.

This application provides semiconductor structures and methods of manufacturing the same. A semiconductor structure includes: an N-type semiconductor layer, a light emitting layer, and a P-type ion doped layer that are disposed from bottom to up, wherein the P-type ion doped layer comprises an activated region and non-activated regions located on two sides of the activated region, P-type doping ions in the activated region are activated, and P-type doping ions in the non-activated region are passivated. The layout of the activated region and the non-activated regions makes an LED include: a high-efficiency light emitting region and light emitting obstacle regions located on two sides of the high-efficiency light emitting region.

A method includes: introducing a gas including gallium, an ammonia gas, and a gas including a p-type impurity to a reactor and forming a first p-type nitride semiconductor layer on a first light-emitting layer in a state in which the reactor has been heated to a first temperature; lowering a temperature of the reactor from the first temperature to a second temperature; introducing an ammonia gas with a first flow rate to the reactor and increasing the temperature of the reactor from the second temperature to a third temperature; and introducing a gas including gallium, an ammonia gas with a second flow rate, and a gas including an n-type impurity to the reactor, and forming a second n-type nitride semiconductor layer on the first p-type nitride semiconductor layer in a state in which the reactor has been heated to the third temperature.

A light-emitting diode may include: a first n-doped semiconductor portion; a second p-doped semiconductor portion; an active zone disposed between the first and second portions and including at least one emitting semiconductor portion; a layer that is electrically conductive and optically transparent to at least one wavelength of the UV range configured to be emitted from the emitting portion, the layer being such that the second portion is disposed between the layer and the active zone. The semiconductors of the first portion and of the emitting portion may include compounds including nitrogen atoms as well as atoms of aluminum and/or of gallium. The semiconductor of the second portion may include Al.sub.X2Ga.sub.(1-X2-Y2)In.sub.Y2N that is p-doped with magnesium atoms, wherein X2>0, Y2>0, and X2+Y2<1, and in which the atomic concentration of magnesium is greater than 10.sup.17 at/cm.sup.3. The electrically conductive layer may include doped diamond.

A light emitting element comprises a semiconductor structure which includes an n-side layer, a p-side layer, and an ultraviolet light emitting active layer positioned between the n-side layer and the p-side layer, each being made of a nitride semiconductor, an n-electrode electrically connected to the n-side layer, and a p-electrode electrically connected to the p-side layer. The active layer has a well layer containing Al, a barrier layer containing Al, and holes defined by the lateral faces of the well layer and the lateral faces of the barrier layer. The p-side layer has a first layer containing Al, a second layer containing Al disposed on the first layer and in contact with the lateral faces of the well layer, and a third layer disposed on the second layer. The third layer is smaller in thickness than the first layer.

A method of forming a Light Emitting Diode (LED) precursor is provided. The method comprises forming a LED stack comprising a plurality of Group III-nitride layers on a substrate, the LED stack comprising a LED stack surface formed on an opposite side of the LED stack to the substrate, and masking a first portion of the LED stack surface, leaving a second portion of the LED stack surface exposed. The second portion of the LED stack surface is subjected to a resistivity changing process such that a second region of the LED stack below the second portion of the LED stack surface comprising at least one of the Group III-nitride layers of the LED stack has a relatively higher resistivity than a resistivity of the respective Group-III nitride layer in a first region of the LED stack below the first portion of the LED stack surface.