Disclosed are a solar cell including an upper cell includes an upper passivation layer disposed on an upper surface of a functional layer, a transparent electrode disposed on an upper surface of the upper passivation layer, an upper first charge transport layer disposed on an upper surface of the transparent electrode, an upper electrode disposed on the upper first of the transparent electrode to be adjacent to the upper surface charge transport layer, an upper second charge transport layer disposed on the upper surface of the functional layer to be spaced apart from the upper passivation layer, the transparent electrode, the upper first charge transport layer, and the upper electrode, and an upper absorption layer disposed on the upper passivation layer, the transparent electrode, the upper first charge transport layer, and the upper second charge transport layer.

Disclosed are a solar cell including an upper cell includes an upper passivation layer disposed on an upper surface of a functional layer, a transparent electrode disposed on an upper surface of the upper passivation layer, an upper first charge transport layer disposed on an upper surface of the transparent electrode, an upper electrode disposed on the upper first of the transparent electrode to be adjacent to the upper surface charge transport layer, an upper second charge transport layer disposed on the upper surface of the functional layer to be spaced apart from the upper passivation layer, the transparent electrode, the upper first charge transport layer, and the upper electrode, and an upper absorption layer disposed on the upper passivation layer, the transparent electrode, the upper first charge transport layer, and the upper second charge transport layer.

The present inventive concept relates to a thin film type solar cell including a plurality of unit cells serially connected to one another on a substrate; and a light transmission part provided in the plurality of unit cells, wherein the light transmission part is provided in a discontinuous rectilinear structure including at least one disconnection part.

According to the present inventive concept, since the light transmission part is discontinuously formed, the repetition characteristic of the light transmission part including a plurality of dot patterns may be reduced, thereby effectively solving a problem where a wave pattern such as a moire phenomenon occurs when light is passing through the light transmission part.

The present inventive concept relates to a thin film type solar cell including a plurality of unit cells serially connected to one another on a substrate; and a light transmission part provided in the plurality of unit cells, wherein the light transmission part is provided in a discontinuous rectilinear structure including at least one disconnection part.

According to the present inventive concept, since the light transmission part is discontinuously formed, the repetition characteristic of the light transmission part including a plurality of dot patterns may be reduced, thereby effectively solving a problem where a wave pattern such as a moire phenomenon occurs when light is passing through the light transmission part.

There is provided a solar panel including: solar cells each of which is formed in a belt-shape extending in a predetermined direction on a plate-shaped surface and which are disposed in rows in a cell-width direction; a partition area that divides the solar cells from each other; and a connecting part that connects adjoining solar cells among the solar cells electrically in series at respective ends in the extending direction. The solar cells have, across at least two of the solar cells, a transparent power generation area in which a power generation area and a transparent area are alternately disposed in the extending direction. The transparent power generation area extends over an entire cell width of at least one of the solar cells, and the connecting part is disposed at each of opposite ends in the extending direction of the at least one solar cell.

There is provided a solar panel including: solar cells each of which is formed in a belt-shape extending in a predetermined direction on a plate-shaped surface and which are disposed in rows in a cell-width direction; a partition area that divides the solar cells from each other; and a connecting part that connects adjoining solar cells among the solar cells electrically in series at respective ends in the extending direction. The solar cells have, across at least two of the solar cells, a transparent power generation area in which a power generation area and a transparent area are alternately disposed in the extending direction. The transparent power generation area extends over an entire cell width of at least one of the solar cells, and the connecting part is disposed at each of opposite ends in the extending direction of the at least one solar cell.

Methods of fabricating solar cells having a plurality of sub-cells coupled by cell level interconnection, and the resulting solar cells, are described herein. In an example, a solar cell includes a plurality of sub-cells. Each of the plurality of sub-cells includes a singulated and physically separated semiconductor substrate portion. Each of the plurality of sub-cells includes an on-sub-cell metallization structure interconnecting emitter regions of the sub-cell. An inter-sub-cell metallization structure couples adjacent ones of the plurality of sub-cells. The inter-sub-cell metallization structure is different in composition from the on-sub-cell metallization structure.

Methods of fabricating solar cells having a plurality of sub-cells coupled by cell level interconnection, and the resulting solar cells, are described herein. In an example, a solar cell includes a plurality of sub-cells. Each of the plurality of sub-cells includes a singulated and physically separated semiconductor substrate portion. Each of the plurality of sub-cells includes an on-sub-cell metallization structure interconnecting emitter regions of the sub-cell. An inter-sub-cell metallization structure couples adjacent ones of the plurality of sub-cells. The inter-sub-cell metallization structure is different in composition from the on-sub-cell metallization structure.

According to one embodiment, a solar cell includes first and second conductive layers, first and second counter conductive layers, first and second photoelectric conversion layers, first and second compound layers. The first counter conductive layer includes a first conductive region. A direction from the first conductive layer to the first conductive region is along a first direction. The first compound layer includes a first compound region provided between the first photoelectric conversion layer and the first conductive region. A second direction from the first conductive layer to the second conductive layer crosses the first direction. The second counter conductive layer includes a second conductive region electrically connected with the first conductive layer. A direction from the second conductive layer to the second conductive region is along the first direction. A direction from the first conductive region to the second conductive region is along the second direction.

According to one embodiment, a solar cell includes first and second conductive layers, first and second counter conductive layers, first and second photoelectric conversion layers, first and second compound layers. The first counter conductive layer includes a first conductive region. A direction from the first conductive layer to the first conductive region is along a first direction. The first compound layer includes a first compound region provided between the first photoelectric conversion layer and the first conductive region. A second direction from the first conductive layer to the second conductive layer crosses the first direction. The second counter conductive layer includes a second conductive region electrically connected with the first conductive layer. A direction from the second conductive layer to the second conductive region is along the first direction. A direction from the first conductive region to the second conductive region is along the second direction.