To provide a photoelectric conversion element, including a first substrate, a first transparent electrode disposed on the first substrate, a hole-blocking layer disposed on the first transparent electrode, an electron-transporting layer that is disposed on the hole-blocking layer and includes an electron-transporting semiconductor on a surface of which a photosensitizing compound is adsorbed, a hole-transporting layer that is connected to the electron-transporting layer and includes a hole-transporting material, and a second electrode disposed on the hole-transporting layer, wherein the photoelectric conversion element includes an output extraction terminal part configured to extract electricity out from the photoelectric conversion element, and the output extraction terminal part is formed with a plurality of micropores piercing through the hole-blocking layer.

The flexible solar panel includes a polymer matrix and a plant extract incorporated in the polymer matrix. The plant extract can be an extract of chard (B. vulgaris subsp. cicla) including an organic dye. The plant extract can include chloroplasts. The polymer matrix may be formed from either poly(vinyl alcohol) or polystyrene. The flexible solar panel can be green.

A composite photovoltaic structure having the following components is illustrated. A first photovoltaic unit is disposed on a transparent substrate, and electrically connected to a second photovoltaic unit in parallel, and the second photovoltaic unit is stacked on the first photovoltaic unit. The first photovoltaic unit is disposed on a second transparent electrode layer, and a first transparent conductive layer is disposed on a top of the first photovoltaic unit and electrically connected to a first transparent electrode layer, and the second photovoltaic unit is disposed on the first transparent conductive layer. A second transparent conductive layer is disposed on the second photovoltaic unit and is electrically connected to the second transparent electrode layer. Thus, the composite photovoltaic structure has a photoelectric reaction area of a significantly improved omnidirectional concentration gain, an efficiently induced current and a low manufacturing cost, without affecting the whole structure thickness.

A manufacturing method of a composite photovoltaic structure including a step of forming a transparent electrode material, a step of forming a first photovoltaic unit, a step of forming a first insulation layer, a step of forming a first transparent conductive layer, a step of forming a second photovoltaic unit, a step of forming a second insulation layer, a step of forming a second transparent conductive layer and a step of splitting a product. Thus, the manufacturing method of the composite photovoltaic structure has a photoelectric reaction area of a significantly improved omnidirectional concentration gain, an efficiently induced current and a low manufacturing cost, without affecting the whole structure thickness.

The present invention relates to an optoelectronic device including an electron transport layer (ETL) and a light harvesting layer, wherein the light harvesting layer includes a metal halide perovskite and is provided on the ETL being a multilayer structure having at least two layers of metal oxide, at least one layer of which includes a crystalline mesoporous metal oxide and at least one layer of which includes an amorphous metal oxide or metal oxide nanocrystals, and wherein the layer being in contact with the light harvesting layer includes the amorphous metal oxide or the metal oxide nanocrystals and is provided on the layer including the crystalline mesoporous metal oxide.

A perovskite solar cell and a method of manufacturing the same are provided. The perovskite solar cell includes a first electrode, a second electrode, an active layer, a hole transporting layer, electron transporting layer, and a passivation layer. The second electrode is disposed opposite to the first electrode. The active layer is disposed between the first electrode and the second electrode, and the active layer includes a perovskite layer. The hole transporting layer is disposed between the first electrode and the active layer. The electron transporting layer is disposed between the second electrode and the active layer. The passivation layer is disposed between the active layer and the electron transporting layer, and the passivation layer includes a dipolar ion having a heteroaryl group.

A photochemical electrode includes: an electrically conductive layer; and a photoexcitation material layer provided over the electrically conductive layer and including a photoexcitation material, wherein the photoexcitation material layer is one of a first photoexcitation material layer in which a potential of the conduction band minimum decreases from a second surface opposite to a first surface on the side of the electrically conductive layer toward the first surface and a second photoexcitation material layer in which a potential of the valence band maximum decreases from the second surface toward the first surface.

To provide a perovskite solar cell having a high conversion efficiency. An organic-inorganic hybrid material applicable to a perovskite solar cell having a first electrode, an electron transport compound layer arranged on the first electrode, a perovskite compound layer arranged on the electron transport compound layer, a hole transport layer arranged on the perovskite compound layer, and a second electrode arranged on the hole transport layer, the organic-inorganic hybrid material comprising a compound represented by K.sub.xA1.sub.yA2.sub.zPbX1.sub.pX2.sub.q. Wherein, K represents potassium, Pb represents lead, A1 and A2 represent freely selectable cations, which may be organic or inorganic, and may be same; X1 and X2 represent halogen atoms, which may be same; x represents a numerical value ranging from 0.01 to 0.20; and y, z, p and q represent freely selectable numerical values which satisfy x+y+z=1 and p+q=3.

The present invention relates to a polymer, an organic solar cell comprising the polymer, and a perovskite solar cell comprising the polymer. The polymer according to the present invention has excellent absorption ability for visible light and an energy level suitable for the use as an electron donor compound in a photo-active layer of the organic solar cell, thereby increasing the light conversion efficiency of the organic solar cell. In addition, the polymer according to the present invention has high hole mobility, and is used as a compound for a hole transport layer, and thus can improve efficiency and service life of the perovskite solar cell without an additive.

In one aspect, nanostructured films are described herein comprising controlled architectures on multiple length scales (e.g. 3). As described further herein, the ability to control film properties on multiple length scales enables tailoring structures of the films to specific applications including, but not limited to, optoelectronic, catalytic and photoelectrochemical cell applications. In some embodiments, a nanostructured film comprises a porous inorganic scaffold comprising particles of an electrically insulating inorganic oxide. An electrically conductive metal oxide coating is adhered to the porous inorganic scaffold, wherein the conductive metal oxide coating binds adjacent particles of the insulating inorganic oxide.