High-performance perovskite solar cell (PSC) devices, arrays thereof, and modules manufactured on flexible and stretchable substrates using roll-to-roll high throughput manufacturing techniques. The flexible cells can be cut into strips and are connected via flexible and/or stretchable interconnects. The interconnect can be a layer deposited on a wavy surface of the stretchable substrate, a coiled or hinged wire, or a conductive paste that can be deformed prior to curing. The highly deformable solar modules can conform to complex organic contours and shapes, such as those that are common in vehicle designs. Such shapes typically require at least one axis of flex and at least one axis of stretch.

A polymer solar cell including a cathode buffer layer (CBL) is proposed. the CBL may include a reaction product between a conjugate polymer electrolyte and an acid derivative, the conjugate polymer electrolyte is poly [(9,9-bis 3′-(N,N-dimethylamino) propyl)-2,7-fluorene)-alt-2,7-(9,9-dihexylfluorene)] (PFN), and the acid derivative is trifluoroacetic acid (CF3AA), 4-trifluoromethyl benzoic acid (CF3BA), or 4-toluene sulfonic acid (TsOH). The CBL including the conjugate polymer electrolyte (PFN) modified with a specific acid derivative may improve short-circuit current (J.sub.sc) and a filling factor (FF) simultaneously, and thus, significantly improved efficiency is exhibited.

An photoelectric conversion element in the disclosure is characterized by including: a first conductive layer; a porous hole-blocking layer disposed on the first conductive layer; a porous insulator layer disposed on the porous hole-blocking layer; photoabsorption layers disposed in a pore of the porous hole-blocking layer and in a pore of the porous insulator layer and containing an organic-based photoelectric conversion material; an electron-blocking layer disposed on the porous insulator layer; and a second conductive layer disposed on the electron-blocking layer.

The present disclosure relates to a device that includes a first layer that includes at least one of a semiconducting material, a hole transport material (HTM), and/or an electron transport material (ETM), a second layer, and a third layer that includes a material that is at least one of transparent or conductive, where the second layer is positioned between the first layer and the third layer, the first layer, the second layer, and the third layer are in electrical contact with each other, and the third layer has a first thickness between greater than zero nm and about 100 nm. In some embodiments of the present disclosure, the semiconducting material may include a perovskite.

A doped organic semiconductor is produced using the method of providing an organic semiconductor solution, contacting the organic semiconductor solution with CO.sub.2; and irradiating the organic semiconductor solution with ultraviolet light. A composition is described, the composition comprising an organic semiconductor; and a metal salt having the formula M.sup.+X.sup.− wherein X.sup.− is a monoanionic species; and wherein the ratio of M.sup.+ to X.sup.− in the hole transport material is less than about 1.00. An additional composition is described, the composition comprising an organic semiconductor; a metal salt having the formula M.sup.+X.sup.− wherein X.sup.− is a monoanionic species; and a metal carbonate; wherein the total metal content of the composition is approximately equal to the X.sup.− content of the composition.

A device includes a first substrate, a silicon layer supported by the first substrate, and an active glass layer with a layer including a crystal material with a chemical formula ABX.sub.3 supported by a glass substrate. The active glass layer is stacked on the first substrate such that the layer including the crystal material with a chemical formula ABX.sub.3 and silicon layer are arranged between the first substrate and the glass substrate.

The present disclosure relates to a photovoltaic (PV) device that includes a color-conversion layer that includes at least one of a color-tuning layer and/or an intermediate layer and a photovoltaic layer where the color-conversion layer changes the appearance of the PV device when compared to a similar PV device constructed without the color-conversion layer, the color-conversion layer increases a power output of the PV device by at least one of reflecting light to the PV layer or emitting light which is redirected to the PV layer, and the device is at least partially transparent to light in the visible spectrum.

The present disclosure may provide semiconductor perovskite layers and method of making thereof. In some cases, the perovskite layer may comprise a composition of MA.sub.n1FA.sub.n2Cs.sub.n3PbX.sub.3. MA may be methylammonium, FA may be formamidinium, n1, n2, and n3 may independently be greater than 0 and less than 1, and n1 + n2 + n3 may equal 1.

A multicomponent conductive adhesive barrier includes an adhesive layer and a conductive barrier. The adhesive layer includes a doped pressure-sensitive adhesive and the conductive barrier layer is a carbon or metal-based material. A photoelectrode structure includes a substrate, a photoabsorbing layer, a multicomponent conductive adhesive barrier, and an electrocatalyst. A method for fabricating the photoelectrode structure includes applying a photoabsorbing layer to a substrate, preparing an adhesive layer, and forming a multicomponent conductive adhesive barrier by applying a conductive barrier layer to the adhesive layer.

A laminate which allows to obtain an organic thin-film solar cell having excellent output characteristics and transparency is provided. The laminate as above has a titanium oxide layer that is disposed on the member serving as a light-transmissive electrode layer and serves as an electron transport layer. The titanium oxide layer has a thickness of not less than 1.0 nm and not more than 200.0 nm. The titanium oxide layer contains indium oxide and metallic indium, InOx/Ti is not less than 0.50 and not more than 20.00 in atomic ratio, and InM/Ti is less than 0.100 in atomic ratio, where an elemental titanium content is represented by Ti, an indium oxide content is represented by InOx, and a metallic indium content is represented by InM.