A photoelectric conversion module is a photoelectric conversion module including a translucent substrate and one or more photoelectric conversion elements formed on the translucent substrate, wherein each of the photoelectric conversion elements is formed by stacking a transparent conductive film, a first charge transport layer, a power generation layer, and a second charge transport layer made of a porous film containing a carbon material, in this order from the side of the translucent substrate, and a portion of the second charge transport layer of at least one of the photoelectric conversion elements, the portion facing another transparent conductive film adjacent to the transparent conductive film of the photoelectric conversion element is electrically connected to the other transparent conductive film via a conductive layer that is thicker than a thickness of adding up the first charge transport layer and the power generation layer.

Photovoltaic devices having contact layers are described herein. Devices, intermediate structures, and methods for making multilayer contacts for perovskite photovoltaic devices are provided. Embodiments include back contacts for N-I-P structures.

Photovoltaic devices having contact layers are described herein. Devices, intermediate structures, and methods for making multilayer contacts for perovskite photovoltaic devices are provided. Embodiments include back contacts for N-I-P structures.

Photovoltaic devices having contact layers are described herein. Devices, intermediate structures, and methods for making multilayer contacts for perovskite photovoltaic devices are provided. Embodiments include back contacts for N-I-P structures.

Photovoltaic devices having contact layers are described herein. Devices, intermediate structures, and methods for making multilayer contacts for perovskite photovoltaic devices are provided. Embodiments include back contacts for N-I-P structures.

The invention relates to an electrically conductive coating (100) of an electrical component (200) for electrically conductively contacting a first busbar (300) located outside the coating (100), to a use of such an electrically conductive coating (100), to an electrical component (200) having such an electrically conductive coating (100), and to a method for coating an electrical component (200) with such an electrically conductive coating (100).

The invention relates to an electrically conductive coating (100) of an electrical component (200) for electrically conductively contacting a first busbar (300) located outside the coating (100), to a use of such an electrically conductive coating (100), to an electrical component (200) having such an electrically conductive coating (100), and to a method for coating an electrical component (200) with such an electrically conductive coating (100).

A solar cell module of an embodiment comprises a first substrate, a second substrate, a photoelectric conversion layer, a first electrode layer, a second electrode layer, and an extraction electrode layer. The extraction electrode layer includes a metal layer and a transparent conductive layer that are stacked on each other, and is provided in a region on the first substrate that does not overlap the photoelectric conversion layer when the substrate is viewed in plan. The solar cell module further comprises a glass frit portion provided between the second substrate and the extraction electrode layer.

Solar cell modules and methods of fabrication are described. In an embodiment, a pair of tandem solar cells are a step surface or trench within the top subcell of a tandem solar cell is at least partially filled with another material such as an insulator support or electrically conductive support to transfer stress away from the absorber layer of the top subcell of the tandem solar cells when stacked or connected with ribbon.

Solar cell modules and methods of fabrication are described. In an embodiment, a pair of tandem solar cells are a step surface or trench within the top subcell of a tandem solar cell is at least partially filled with another material such as an insulator support or electrically conductive support to transfer stress away from the absorber layer of the top subcell of the tandem solar cells when stacked or connected with ribbon.