A fabrication method for a flexible bifacial dye-sensitized solar cell is described. The method involves forming a flexible counter electrode of crystalline Pt nanoparticles on a first conductive layer by irradiating a precursor solution with a UV lamp. A flexible photoanode is formed by applying metal oxide particles to a second conductive layer, and then the solar cell is constructed by sandwiching an electrolyte between the counter electrode and photoanode.

A dye-sensitized solar cell includes: a transparent electrode; a power generation layer on the first main surface of the transparent electrode, including a semiconductor layer, a photosensitizing dye and an electrolyte layer; a counter electrode on the main surface of the power generation layer, having an electrode extraction region, wherein at least a part of the side surfaces of the counter electrode and at least a part of the side surfaces of the power generation layer are positioned coplanar, the electrode extraction region of the counter electrode overlaps with at least a part of the main surface of the power generation layer in a top view, and the side surfaces of the power generation layer are covered with a sealing layer formed extending from one of the transparent electrode and the counter electrode to the other.

A photoelectric conversion element includes a conductive support, a photoconductor layer including an electrolyte, a charge transfer layer including an electrolyte, and a counter electrode, in which the photoconductor layer has semiconductor fine particles carrying a metal complex dye represented by a specific formula.

The invention provides a dye-sensitized solar cell module that is capable of achieving high electrical power. The invention provides a dye-sensitized solar cell module in which photoelectrodes and counter electrodes are disposed opposite to each other in a T-shape via an electrolyte layer.

A method for fabricating a solar cell is provided and has steps of: providing a transparent conductive substrate; forming a porous supporting layer on the transparent conductive substrate; forming a porous conductive counter electrode layer on the porous supporting layer, where the porous conductive counter electrode layer includes a carrier blocking layer and a conductive layer, and the carrier blocking layer is between the porous supporting layer and the conductive layer; and providing a light-absorbing material penetrating from the porous conductive counter electrode layer. The light-absorbing material fills within the porous supporting layer through a plurality of pores in the porous conductive counter electrode layer.

Disclosed are a dye-sensitized solar cell including a polymer/graphene composite gel electrolyte and methods of preparing the dye-sensitized solar cell.

A solar cell module (100) includes: one or more cells that are enclosed by a barrier packaging material (13A, 13B) and that include first and second base plates (3, 7) and a functional layer; and first and second lead-out electrodes (11A, 11B) that are respectively connected to electrodes (2, 6) disposed at the sides of the respective base plates (3, 7) via electrical connectors (12A, 12B). The electrical connectors (12A, 12B) are separated from the functional layer in a base plate surface direction. The lead-out electrodes (11A, 11B) are disposed on an outer surface of the barrier packaging material (13A, 13B). Gaps between the barrier packaging material (13A, 13B) and the lead-out electrodes (11A, 11B) are sealed by a lead-out electrode seal (15).

Provided is a solar cell comprising a first electrode; a second electrode; a photoabsorber layer located between the first electrode and the second electrode; a first semiconductor layer located between the first electrode and the photoabsorber layer; and a second semiconductor layer located between the second electrode and the photoabsorber layer. At least one electrode selected from the group consisting of the first electrode and the second electrode is light-transmissive. The photoabsorber layer contains a perovskite compound represented by the composition formula AMX.sub.3 (where A represents a monovalent cation, M represents a divalent cation, and X represents a halogen anion). The first semiconductor layer contains Li. The second semiconductor layer contains LiN(SO.sub.2CnF.sub.2n+1).sub.2 (where n is a natural number of not less than 2).

A dye-sensitized solar cell formed by layering a conductive layer; a photoelectric conversion layer in which a dye is adsorbed in a porous semiconductor layer and the layer is filled with a carrier transporting material; and a counter electrode including only a counter electrode conductive layer or including a catalyst layer and a counter electrode conductive layer on a support made of a light transmitting material, in which the photoelectric conversion layer is brought into contact with the counter electrode; the porous semiconductor layer forming the photoelectric conversion layer has two or more layers with different light scattering properties; and the two or more porous semiconductor layers are layered in an order of from a layer with lower light scattering property to a layer with higher light scattering property from a light receiving face side of the dye-sensitized solar cell.

A fiber-shaped electric energy harvesting and storage device includes a substrate having a fiber shape, a lithium ion storage unit disposed to surround the substrate, and a plurality of photoelectric conversion units disposed to surround the lithium ion storage unit.