Abstract: Disclosed is a multi-quantum well structure including a stress relief layer, an electron-collecting layer disposed on the stress relief layer, and an active layer including a first active layer unit that is disposed on the electron-collecting layer. The first active layer unit includes potential barrier sub-layers and potential well sub-lavers being alternately stacked, in which at least one of the potential barrier sub-layers has a GaN/Alx1Iny1Ga(1-x1-y1)N stack, where 0<x1?1 and 0?y1<1. An LED device including the multi-quantum well structure is also disclosed.

Abstract: Disclosed is a multi-quantum well structure including a stress relief layer, an electron-collecting layer disposed on the stress relief layer, and an active layer including a first active layer unit that is disposed on the electron-collecting layer. The first active layer unit includes potential barrier sub-layers and potential well sub-layers being alternately stacked, in which at least one of the potential barrier sub-layers has a GaN/Alx1Iny1Ga(1-x1-y1)N/GaN stack, where 0<x1?1 and 0?y1<1, and for the remainder of the potential barrier sub-layers, each of the potential barrier sub-layers is a GaN layer. An LED device including the multi-quantum well structure is also disclosed.

Abstract: Disclosed is a multi-quantum well structure including a stress relief layer, an electron-collecting layer disposed on the stress relief layer, and an active layer including a first active layer unit that is disposed on the electron-collecting layer. The first active layer unit includes potential barrier sub-layers and potential well sub-layers being alternately stacked, in which at least one of the potential barrier sub-layers has a GaN/Alx1Iny1Ga(1-x1-y1)N/GaN stack, where 0<x1?1 and 0?y1<1, and for the remainder of the potential barrier sub-layers, each of the potential barrier sub-layers is a GaN layer. An LED device including the multi-quantum well structure is also disclosed.

Abstract: A nitride white-light LED includes: a substrate; an epitaxial layer; an N-type electrode and a P-type electrode; channels are formed on the substrate and the epitaxial layer; temperature isolation layers are formed with low thermal conductivity material thereon to form three independent temperature zones (Zones I/II/III) on a single chip; temperature control layers are formed with high thermal conductivity material on the side wall of the epitaxial layer and the back surface of the substrate at Zones I/II/III, and control temperature of the epitaxial layer and the substrate; based on different thermal expansion coefficients, lattice constants of the nitride and the substrate at Zones I/II/III are regulated to adjust the biaxial stress to which the nitride; quantum wells change conduction band bottom and valence band top positions to change forbidden band widths and light-emitting wavelengths; the LED can emit red, green and blue lights by a single chip.

Abstract: A nitride white-light LED includes: a substrate; an epitaxial layer; an N-type electrode and a P-type electrode; channels are formed on the substrate and the epitaxial layer; temperature isolation layers are formed with low thermal conductivity material thereon to form three independent temperature zones (Zones I/II/III) on a single chip; temperature control layers are formed with high thermal conductivity material on the side wall of the epitaxial layer and the back surface of the substrate at Zones I/II/III, and control temperature of the epitaxial layer and the substrate; based on different thermal expansion coefficients, lattice constants of the nitride and the substrate at Zones I/II/III are regulated to adjust the biaxial stress to which the nitride; quantum wells change conduction band bottom and valence band top positions to change forbidden band widths and light-emitting wavelengths; the LED can emit red, green and blue lights by a single chip.

Abstract: A nitride light emitting diode includes: an n-type nitride layer, a light emitting layer and a p-type nitride layer in sequence, wherein, the light emitting layer is a MQW structure composed of a barrier layer and a well layer, in which, an AlGaN electron tunneling layer is inserted into at least one well layer closing to the n-type nitride layer with barrier height greater than that of the barrier layer; in addition, the barriers of the AlGaN electron tunneling layer and the well layer are high enough so that electrons are difficult to transit towards thermionic emission direction, but mainly transit through tunneling in the InGaN well layers, which confines electron mobility and adjusts electron distribution. Hence, electrons have less chance to spill over into the P-type nitride layer.

Abstract: A light emitting diode (LED) includes quantum dots serving as the quantum well layer in the multiple-quantum well (MQW) structure, which can greatly improve the combination efficiency of electrons and holes due to quantum confinement effect; a nanoscale metal reflective layer is formed between the quantum barrier layer with nanoscale pits to instantly reflect the light emitted downwards from the MQW to the front of epitaxial structure; in addition, the nanoscale metal reflective layer can form surface plasmon to further improve light emitting efficiency.