Abstract: A monofacial or bifacial crystalline solar cell, on the front face of which over the entire area a first surface passivation layer is arranged directly on the semiconductor interface and above this a first optically opaque, electrically conductive material is arranged in first lateral regions as a front face contact, and a first optically transparent, electrically conductive material is arranged exclusively in second lateral regions. The first optically transparent, electrically conductive material is electrically conductively connected to the front face contact and to a first region of the semiconductor material of the solar cell. The method provides for application of the first optically transparent, electrically conductive material only after the first optically opaque, electrically conductive material has been applied, in such a way that firing of the front face contact is avoided.

Abstract: A monofacial or bifacial crystalline solar cell, on the front face of which over the entire area a first surface passivation layer is arranged directly on the semiconductor interface and above this a first optically opaque, electrically conductive material is arranged in first lateral regions as a front face contact, and a first optically transparent, electrically conductive material is arranged exclusively in second lateral regions. The first optically transparent, electrically conductive material is electrically conductively connected to the front face contact and to a first region of the semiconductor material of the solar cell. The method provides for application of the first optically transparent, electrically conductive material only after the first optically opaque, electrically conductive material has been applied, in such a way that firing of the front face contact is avoided.

Abstract: A solar cell with a semiconductor body and with a contact layout for electrically connecting a surface of the semiconductor body, including: a plurality of current collecting contact fingers, which are disposed substantially parallel to each other, wherein the contact finger respectively has a line resistance of at least 100 ?/m, a plurality of busbars, which are electrically connected to the contact fingers, and at least one cell connector continuously connecting the busbar, wherein the contact fingers and the busbar are dimensioned, particularly in terms of the material properties thereof, layout on the semiconductor body thereof, width and layer thickness thereof, that the contact layout has a series resistance of maximum 1 ?cm2.

Abstract: A device for detecting electrical properties of a sample of an excitable material, in particular of a silicon wafer, comprises a microwave source for generating a microwave field, a resonance system which is coupled to the microwave source in a microwave-transmitting manner, the resonance system comprising a microwave resonator with at least one opening and a sample to be examined which is arranged next to the at least one opening, at least one excitation source which is arranged in the surroundings of the sample for controlled electrical excitation of the sample, and a measuring device for measuring at least one physical parameter of the resonance system.

Abstract: A device for detecting electrical properties of a sample of an excitable material, in particular of a silicon wafer, comprises a microwave source for generating a microwave field, a resonance system which is coupled to the microwave source in a microwave-transmitting manner, the resonance system comprising a microwave resonator with at least one opening and a sample to be examined which is arranged next to the at least one opening, at least one excitation source which is arranged in the surroundings of the sample for controlled electrical excitation of the sample, and a measuring device for measuring at least one physical parameter of the resonance system.