Abstract: A flip-chip light-emitting diode chip with a patterned transparent bonding layer includes: an epitaxial laminated layer, having an upper surface and a lower surface opposite to each other, which further includes an n-type semiconductor layer, an active layer and a p-type semiconductor layer. Part of the n-type semiconductor layer and the active layer are etched to expose part of the p-type semiconductor layer. A first electrode is over the surface of the n-type semiconductor layer, and a second electrode is over the surface of the exposed p-type semiconductor layer. A transparent medium layer over the upper surface of the epitaxial laminated layer, wherein the upper surface is provided with a grid-shaped or array-shaped recess region. A patterned transparent bonding medium layer fills up the recess region of the transparent medium layer, and the upper surface is at the same plane with the upper surface of the transparent medium layer.

Abstract: A flip-chip light-emitting diode chip with a patterned transparent bonding layer includes: an epitaxial laminated layer, having an upper surface and a lower surface opposite to each other, which further includes an n-type semiconductor layer, an active layer and a p-type semiconductor layer. Part of the n-type semiconductor layer and the active layer are etched to expose part of the p-type semiconductor layer. A first electrode is over the surface of the n-type semiconductor layer, and a second electrode is over the surface of the exposed p-type semiconductor layer. A transparent medium layer over the upper surface of the epitaxial laminated layer, wherein the upper surface is provided with a grid-shaped or array-shaped recess region. A patterned transparent bonding medium layer fills up the recess region of the transparent medium layer, and the upper surface is at the same plane with the upper surface of the transparent medium layer.

Abstract: A flip-chip multi junction solar cell chip integrated with a bypass diode includes from up to bottom: a glass cover; a transparent bonding layer; a front electrode; an n/p photoelectric conversion layer; a p/n tunnel junction; a structure layer of the n/p bypass diode; a first backside electrode; a second backside electrode. The solar cell chip also includes at least a through hole extending through the n/p photoelectric conversion layer, the p/n tunnel junction and the structure layer of the n/p bypass diode. An ultra-thin substrate-less cell can therefore be provided without occupying effective light receiving areas, greatly improving cell heat dissipation. With a light weight, the chip can also have advantages in space power application.

Abstract: A four-junction quaternary compound solar cell and a method thereof are provided. Forming a first subcell (100) with a first band gap, a lattice constant matching with the substrate on an InP grown substrate, forming a second subcell (200) with a second band gap bigger than the first band gap, a lattice constant matching with the substrate on the first subcell, forming a graded buffer layer (600) with a third band gap bigger than the second band gap on the second subcell, forming a third subcell (300) with a fourth band gap bigger than the third band gap, a lattice constant smaller than the substrate on the graded buffer layer, forming a fourth subcell (400) with a fifth band gap bigger than the fourth band gap, a lattice constant matching with the third subcell on the third subcell, and then forming the required four-junction solar cell then by succeeding process including removing the grown substrate, bonding a support substrate, forming electrodes, evaporating an anti-reflect film and so on.

Abstract: A fabrication method for an inverted solar cell includes: (1) providing a growth substrate; (2) depositing a SiO2 mask layer over the surface of the growth substrate to form a patterned substrate; (3) forming a sacrificial layer with epitaxial growth over the patterned substrate, wherein the sacrificial layer encompasses the entire SiO2 mask pattern; (4) forming a buffer layer over the sacrificial layer via epitaxial growth; (5) forming a semiconductor material layer sequence of the inverted solar cell over the buffer layer with epitaxial growth; (6) bonding the semiconductor material layer sequence of the inverted solar cell with a supporting substrate; (7) selectively etching the SiO2 mask layer by wet etching; and (8) selectively etching the sacrificial layer by wet etching to lift off the growth substrate.

Abstract: A flip-chip solar cell chip includes a bonding transfer substrate; a metal bonding layer; a flip-chip solar cell epitaxial layer that bonds with the bonding transfer substrate with the metal bonding layer; the flip-chip solar cell epitaxial layer and the metal bonding layer are divided into two or more portions; the surface of the flip-chip solar cell epitaxial layer has a front electrode; and the metal bonding layer is connected with the ends of the front electrode to form a series connection of the divided epitaxial layer. Advantageously, the division of the solar cell epitaxial layer into a plurality of completely-separated portions greatly reduces photo currents and power loss of cell chip series resistance while realizing multiplied increase of output voltage, thereby improving photoelectric conversion efficiency. The use of metal bonding layer as the back electrode realizes extremely low resistance loss of the back electrode.

Abstract: A high-concentration solar cell includes an epitaxial layer structure, an upper patterned electrode on the top surface, and a back electrode on the back surface. The upper patterned electrode includes a primary pattern and a secondary pattern, where the primary pattern is composed of a series of small metal isosceles trapezoids around the perimeter of the cell. The narrower base of each metal trapezoid points toward an interior of the cell. A lead soldering pad is located within each metal trapezoid for being soldered to an external conductor for carrying the solar cell current. The secondary pattern consists of thin spaced conductors that connect to the angled sides and base of each trapezoid and spread current across the top surface of the cell. The current along the angled sides of each trapezoid is well-distributed to all the spaced conductors connected to the angled sides to avoid current crowding.

Abstract: A four-junction quaternary compound solar cell and a method thereof are provided.

Abstract: A fabrication method for an inverted solar cell includes: (1) providing a growth substrate; (2) depositing a SiO2 mask layer over the surface of the growth substrate to form a patterned substrate; (3) forming a sacrificial layer with epitaxial growth over the patterned substrate, wherein the sacrificial layer encompasses the entire SiO2 mask pattern; (4) forming a buffer layer over the sacrificial layer via epitaxial growth; (5) forming a semiconductor material layer sequence of the inverted solar cell over the buffer layer with epitaxial growth; (6) bonding the semiconductor material layer sequence of the inverted solar cell with a supporting substrate; (7) selectively etching the SiO2 mask layer by wet etching; and (8) selectively etching the sacrificial layer by wet etching to lift off the growth substrate.

Abstract: A high-concentration solar cell includes an epitaxial layer structure, an upper patterned electrode on the top surface, and a back electrode on the back surface. The upper patterned electrode includes a primary pattern and a secondary pattern, where the primary pattern is composed of a series of small metal isosceles trapezoids around the perimeter of the cell. The narrower base of each metal trapezoid points toward an interior of the cell. A lead soldering pad is located within each metal trapezoid for being soldered to an external conductor for carrying the solar cell current. The secondary pattern consists of thin spaced conductors that connect to the angled sides and base of each trapezoid and spread current across the top surface of the cell. The current along the angled sides of each trapezoid is well-distributed to all the spaced conductors connected to the angled sides to avoid current crowding.

Abstract: A high-concentration multi-junction solar cell and method for fabricating same is provided. The high-concentration multi-junction solar cell comprises a top cell, an intermediate cell, a bottom cell and two tunneling junctions connecting the top cell and intermediate cell and the intermediate cell and bottom cell. The emitter layers of the top and intermediate cells both employ the graded doping concentrations and have high open circuit voltage and short circuit current. The top cell emitter layer is over several hundred nanometers thicker than that of the traditional multi-junction cell so as to decrease the whole series resistance of the multi-junction cell, improve the fill factor, and gain higher photoelectric conversion efficiency.