A stacked monolithic multijunction solar cell, which includes a first subcell having a p-n junction with an emitter layer and a base layer, the thickness of the emitter layer being less than the thickness of the base layer at least by a factor of ten, and the first subcell comprising a substrate having a semiconductor material from the groups III and V or a substrate from the group IV, and which further includes a second subcell arranged on the first subcell and a third subcell arranged on the second subcell, the two subcells each including an emitter layer and a base layer, and a tunnel diode and a back side field layer each being formed between the subcells, the thickness of the emitter layer being greater than the thickness of the base layer in each case between the second subcell and in the third subcell.

A stacked monolithic multijunction solar cell, which includes a first subcell having a p-n junction with an emitter layer and a base layer, the thickness of the emitter layer being less than the thickness of the base layer at least by a factor of ten, and the first subcell comprising a substrate having a semiconductor material from the groups III and V or a substrate from the group IV, and which further includes a second subcell arranged on the first subcell and a third subcell arranged on the second subcell, the two subcells each including an emitter layer and a base layer, and a tunnel diode and a back side field layer each being formed between the subcells, the thickness of the emitter layer being greater than the thickness of the base layer in each case between the second subcell and in the third subcell.

The present disclosure relates to a method that includes contacting a surface of a first layer that includes a Group III element and a Group V element with a gas that includes HCl, where the first layer is positioned in thermal contact with a wafer positioned in a chamber of a reactor, and the contacting results in a roughening of the surface.

The present disclosure relates to a method that includes contacting a surface of a first layer that includes a Group III element and a Group V element with a gas that includes HCl, where the first layer is positioned in thermal contact with a wafer positioned in a chamber of a reactor, and the contacting results in a roughening of the surface.

A multijunction solar cell including an upper first solar subcell having a first band gap and positioned for receiving an incoming light beam; a second solar subcell disposed below and adjacent to and lattice matched with said upper first solar subcell, and having a second band gap smaller than said first band gap; wherein at least one of the solar cells has a graded band gap throughout its thickness.

A multijunction solar cell including an upper first solar subcell having a first band gap and positioned for receiving an incoming light beam; a second solar subcell disposed below and adjacent to and lattice matched with said upper first solar subcell, and having a second band gap smaller than said first band gap; wherein at least one of the solar cells has a graded band gap throughout its thickness.

A multijunction solar cell including a substrate and a top (or light-facing) solar subcell having an emitter layer, a base layer, and a window layer adjacent to the emitter layer, the window layer composed of a material that is optically transparent, has a band gap of greater than 2.6 eV, and includes an appropriately arranged multilayer antireflection coating on the top surface thereof.

A multijunction solar cell including a substrate and a top (or light-facing) solar subcell having an emitter layer, a base layer, and a window layer adjacent to the emitter layer, the window layer composed of a material that is optically transparent, has a band gap of greater than 2.6 eV, and includes an appropriately arranged multilayer antireflection coating on the top surface thereof.

The invention relates to a method for producing a back-contact solar cell (10), and to a back-contact solar cell (10) comprising a semiconductor substrate (12), in particular a silicon wafer, comprising a front side (16) and a back side (14), the solar cell (10) comprising electrodes (36) of a first polarity and electrodes (38) of a second polarity on the back side, characterized in that that the electrodes (36) of the first polarity are located on a highly doped silicon layer (20) of the first polarity, the highly doped silicon layer (20) being located on a first passivation layer (18) located on the semiconductor substrate, and the electrodes (38) of the second polarity directly electrically and mechanically contacting the semiconductor substrate (12) via highly doped base regions (30) of the second polarity of the semiconductor substrate (12).

The invention relates to a method for producing a back-contact solar cell (10), and to a back-contact solar cell (10) comprising a semiconductor substrate (12), in particular a silicon wafer, comprising a front side (16) and a back side (14), the solar cell (10) comprising electrodes (36) of a first polarity and electrodes (38) of a second polarity on the back side, characterized in that that the electrodes (36) of the first polarity are located on a highly doped silicon layer (20) of the first polarity, the highly doped silicon layer (20) being located on a first passivation layer (18) located on the semiconductor substrate, and the electrodes (38) of the second polarity directly electrically and mechanically contacting the semiconductor substrate (12) via highly doped base regions (30) of the second polarity of the semiconductor substrate (12).