The dye-sensitized solar cell comprises a first electrode including a porous semiconductor layer supporting a dye; and a second electrode serving as a counter electrode of the first electrode. The second electrode includes a counter electrode conductive layer containing an absorbent supporting a dye that is the same as or different from the dye supported by the porous semiconductor layer.

A photoelectric conversion device of an embodiment includes: a first photoelectric conversion part including a first transparent electrode provided on a transparent substrate, a first active layer, and a first counter electrode; and a second photoelectric conversion part including a second transparent electrode, a second active layer, and a second counter electrode. A conductive layer containing noble metal as a main component is formed on a partial region of the second transparent electrode, and a fine particle layer having a stack of fine particles is formed on the conductive layer. The first counter electrode and the second transparent electrode are electrically connected by a connection part having a scribe groove penetrating through the fine particle layer from the second active layer and exposing a surface of the conductive layer, and a conductive layer having a part of the first counter electrode filled in the scribe groove.

The dye-sensitized solar cell comprises a first electrode including a porous semiconductor layer supporting a dye, a second electrode serving as the counter electrode of the first electrode, and an electrolytic solution filled between the first electrode and the second electrode. The second electrode includes a counter electrode conductive layer containing carbon microparticles and supporting a dye that is the same as that supported by the porous semiconductor layer.

A photoelectric conversion device in an embodiment includes a first photoelectric conversion part including a first transparent electrode, a first photoelectric conversion layer, and a first counter electrode and a second photoelectric conversion part including a second transparent electrode, a second photoelectric conversion layer, and a second counter electrode, the first photoelectric conversion part and the second photoelectric conversion part being provided on a transparent substrate. The first counter electrode and the second transparent electrode are electrically connected by a connection part. As for the first photoelectric conversion layer and the second photoelectric conversion layer, adjacent portions of the adjacent first and second photoelectric conversion layers are electrically separated by an inactive region having electrical resistance higher than that of the first and second photoelectric conversion layers.

Solar cells use as substrates glass (23) coated with a transparent conductive layer (21), able to collect the electric power generated by the solar cell. This layer (21), normally a TCO, have limited conductivity, implying the use of current collector lines applied in a complex manner. The conductivity of the conductive layer (21) is increased by the application of a structure, in particular a grid, of thin conductive lines (22) inserted in grooves on the glass surface (23) or directly applied on this, followed by a TCO layer coating (21). This highly conductive grid (22) collects the electricity from the TCO layer (21) and directs it to the periphery of the cell. Both glass substrates are sealed by a process employing a precursor of glass surrounding the entire perimeter of the substrate. The glass precursor is heated to its melting point, by a laser, completely sealing the two substrates of the module.

In one aspect, solar energy systems are described herein. In some embodiments, such a comprises an electrochemical cell comprising a photoelectrode, a counter electrode, and an ion transport membrane disposed between the photoelectrode and counter electrode. The cell further comprises a first electrolyte solution disposed in fluid communication with the photoelectrode and the membrane, and a second electrolyte solution disposed in fluid communication with the membrane and the counter electrode. The first and/or second electrolyte solution comprises a solvated redox pair. Additionally, the cell also comprises a storage electrode, a first external electrical connection between the photoelectrode and the counter electrode, and a second external electrical connection between the counter electrode and the storage electrode. Components of the system define a liquid junction photovoltaic cell under light conditions and a galvanic cell under dark conditions.

Processes and formulations for manufacturing a painted circuit are disclosed. In some implementations, a painted circuit can be manufactured using a process including providing a substrate and applying one or more paint layers on a surface of the substrate, where the one or more paint layers each form an electrical component of the painted circuit. A given paint layer of the one or more paint layers can include a conductive paint formulation having a resistance that is defined by a concentration of conductive material that is included in the conductive paint formulation and a thickness of the given paint layer, and lower concentrations of the conductive material included in the conductive paint formulation provide a higher resistance than higher concentrations of conductive material.

Disclosed is a photoelectric conversion element including a cell. The cell includes a first electrode, a second electrode, an oxide semiconductor layer provided on the first electrode, and an electrolyte provided between the first and second electrodes. The second electrode includes an annular portion, an approaching portion approaching the oxide semiconductor layer closer than the annular portion and an annular connecting portion connecting the annular portion and the approaching portion, and the oxide semiconductor layer includes an inner part facing the approaching portion on the first electrode and an annular outer part provided around the inner part and facing the connecting portion. The outer part includes a plurality of linear portions separated from one another and a corner portion connecting two adjacent linear portions to each other, the corner portion is thicker than the linear portion, and the linear portion is thicker than the inner part.

A photoelectric conversion element includes: a transparent substrate; a photoelectric conversion cell disposed on one surface of the transparent substrate; and a conductive first current extracting portion disposed on the one surface of the transparent substrate and that extracts a current from the photoelectric conversion cell. The photoelectric conversion cell includes: an electrode disposed on the one surface of the transparent substrate; a counter substrate that faces the electrode and that has a metal substrate; and sealing portion disposed between the transparent substrate and the counter substrate. The photoelectric conversion element further includes: a first external connecting terminal on the conductive first current extracting portion; a connecting terminal, separated from the first external connecting terminal, disposed on the conductive first current extracting portion between the first external connecting terminal and the sealing portion; and a conductive member that connects the connecting terminal and the metal substrate.

The present disclosure relates to a photosensitive organic capacitor whose capacitance efficiency is increased if light is applied to the photosensitive organic capacitor, and the photosensitive organic capacitor includes an upper substrate and a lower substrate that are spaced apart by a certain interval, an upper electrode and a lower electrode that are attached to each opposing side of the upper substrate and lower substrate, an active layer that is formed between the upper electrode and the lower electrode, and an upper polarization-inducing layer and a lower polarization-inducing layer that are formed between the upper electrode and the active layer and between the lower electrode and the active layer, and that induce the polarization of charges within the active layer if light is applied to the photosensitive organic capacitor.