The invention provides a light emitting semiconductor device comprising a zinc magnesium oxide based layer as active layer, wherein the zinc magnesium oxide based layer comprises an aluminum doped zinc magnesium oxide layer having the nominal composition Zn.sub.1-xMg.sub.xO with 1-350 ppm Al, wherein x is in the range of 0<x0.3. The invention further provides a method for the production of such aluminum doped zinc magnesium oxide, the method comprising heat treating a composition comprising Zn, Mg and Al with a predetermined composition at elevated temperatures, and subsequently annealing the heat treated composition to provide said aluminum doped zinc magnesium oxide.

An integrated hybrid crystal Light Emitting Diode (LED) display device that may emit red, green, and blue colors on a single wafer. The various embodiments may provide double-sided hetero crystal growth with hexagonal wurtzite III-Nitride compound semiconductor on one side of (0001) c-plane sapphire media and cubic zinc-blended III-V or II-VI compound semiconductor on the opposite side of c-plane sapphire media. The c-plane sapphire media may be a bulk single crystalline c-plane sapphire wafer, a thin free standing c-plane sapphire layer, or crack-and-bonded c-plane sapphire layer on any substrate. The bandgap energies and lattice constants of the compound semiconductor alloys may be changed by mixing different amounts of ingredients of the same group into the compound semiconductor. The bandgap energy and lattice constant may be engineered by changing the alloy composition within the cubic group IV, group III-V, and group II-VI semiconductors and within the hexagonal III-Nitrides.

The present invention relates to colloidal quantum dots, to a process for producing such colloidal quantum dots, to the use thereof and to optoelectronic components comprising colloidal quantum dots.

Light-emitting materials are made from a porous light-emitting semiconductor having quantum dots (QDs) disposed within the pores. According to some embodiments, the QDs have diameters that are essentially equal in size to the width of the pores. The QDs are formed in the pores by exposing the porous semiconductor to gaseous QD precursor compounds, which react within the pores to yield QDs. According to certain embodiments, the pore size limits the size of the QDs produced by the gas-phase reactions. The QDs absorb light emitted by the light-emitting semiconductor material and reemit light at a longer wavelength than the absorbed light, thereby down-converting light from the semiconductor material.

Method for producing a light emitting semiconductor device comprising a zinc magnesium oxide based layer as active layer, wherein the zinc magnesium oxide based layer comprises an aluminum doped zinc magnesium oxide layer having the nominal composition Zn.sub.1-xMg.sub.xO with 1-350 ppm Al, wherein x is in the range of 0<x0.3. The invention further provides a method for the production of such aluminum doped zinc magnesium oxide, the method comprising heat treating a composition comprising Zn, Mg and Al with a predetermined composition at elevated temperatures, and subsequently annealing the heat treated composition to provide said aluminum doped zinc magnesium oxide.

The present invention provides a film formation method and a film formation apparatus which can fabricate an epitaxial film with +c polarity by a sputtering method. In one embodiment of the present invention, the film formation method of epitaxially growing a semiconductor thin film with a wurtzite structure by the sputtering method on an epitaxial growth substrate heated to a predetermined temperature by a heater includes the following steps. First, the substrate is disposed on a substrate holding portion including the heater to be located at a predetermined distance away from the heater. Then, the epitaxial film of the semiconductor film with the wurtzite structure is formed on the substrate with the impedance of the substrate holding portion being adjusted.

The present application provides an LED chip based on an alumina-silica composite substrate and a fabrication method thereof. The LED chip comprises an alumina-silica composite PSS substrate, a composite buffer layer and an LED structural layer, wherein the composite buffer layer is epitaxially grown on the alumina-silica composite PSS substrate, and the LED structural layer is epitaxially grown on the composite buffer layer. The composite buffer layer comprises: an aluminium oxynitride/aluminium nitride layer and a silicon oxynitride layer, wherein the alumina in the alumina-silica composite PSS substrate is covered with the aluminium oxynitride/aluminium nitride layer, and the silica in the alumina-silica composite PSS substrate is covered with the aluminium oxynitride/aluminium nitride layer and the silicon oxynitride layer in a staggered manner.

Light-emitting materials are made from a porous light-emitting semiconductor having quantum dots (QDs) disposed within the pores. According to some embodiments, the QDs have diameters that are essentially equal in size to the width of the pores. The QDs are formed in the pores by exposing the porous semiconductor to gaseous QD precursor compounds, which react within the pores to yield QDs. According to certain embodiments, the pore size limits the size of the QDs produced by the gas-phase reactions. The QDs absorb light emitted by the light-emitting semiconductor material and reemit light at a longer wavelength than the absorbed light, thereby down-converting light from the semiconductor material.

A quantum dot light emitting diode, including a first electrode and a second electrode, a quantum dot light emitting layer disposed between the two electrodes, including at least a red quantum dot, a green quantum dot and a blue quantum dot, and a black matrix at least disposed among the red quantum dot, the green quantum dot and the blue quantum dot; one of the first electrode and the second electrode that is located on a light exiting side is at least a transparent electrode. With the quantum dot light emitting diode, a full-color display can be realized, and the aperture ratio of pixels can be effectively enhanced. There are further disclosed a manufacturing method of the quantum dot light emitting diode and a display device.

An optoelectronic device is manufactured by an epitaxial growth, on each first layer of many first layers spaced apart from each other on a first support, wherein the first is made of a first semiconductor material, of a second layer made of a second semiconductor material. A further epitaxial growth is made on each second layer of a stack of semiconductor layers. Each stack includes a third layer made of a third semiconductor material in physical contact with the second layer. Each stack is then separated from the first layer by removing the second layer using an etching that is selective simultaneously over both the first and third semiconductor materials. Each stack is then transferred onto a second support. Each of the first and third semiconductor materials is one of a III-V compound or a II-VI compound.