Provided is a photoelectric conversion element including: a first electrode; a hole blocking layer; an electron transport layer; a hole transport layer; and a second electrode, wherein the hole transport layer contains a compound represented by general formula (1) below, ##STR00001##
where in the formula, R.sub.1 represents a methoxy group or an ethoxy group, R.sub.2 represents a hydrogen group or a methyl group, R.sub.3 represents a hydrogen group, a methyl group, or a methoxy group, R.sub.4 represents a methoxy group, and X represents CH.sub.2, CH.sub.2CH.sub.2, O, or C(CH.sub.2).sub.5.

The dye-sensitized photoelectric conversion element of the present invention has an electrolyte layer in which an ammonium ion, an inorganic salt and an iodide ion are dissolved in an organic solvent and in which the ratio of the molar amount of triiodide ions to the molar amount of iodide ions is less than 1%. High photoelectric conversion efficiency is obtained regardless of the kind of the sensitizing dye, and the design is also excellent.

Disclosed is a photoelectric conversion element including a cell. The cell includes an electrode substrate, a counter substrate, an oxide semiconductor layer provided on the electrode substrate, an electrolyte provided between the electrode substrate and the counter substrate, and an annular sealing portion joining the electrode substrate and the counter substrate. The layer includes a main body portion provided inside the sealing portion and on the electrode substrate and extending straight from the electrode substrate toward the counter substrate, and a protruding portion which protrudes from the main body portion toward the sealing portion and does not come into contact with the electrode substrate. A width of a second surface of the layer facing the counter substrate is longer than a width of a first surface which is a boundary surface between the layer and the electrode substrate in a cross section along a thickness direction of the layer.

The present disclosure describes solution methods for manufacturing perovskite halide films for use in solar cells. The methods include the use of additives that facilitate the formation of transitory, intermediate films that are later transformed into the final target perovskite halide films, such that the final films provide improved physical characteristics and operational performance.

An electrochemical reaction device includes: an electrolytic solution tank to store an electrolytic solution; an oxidation electrode disposed in the electrolytic solution tank; a reduction electrode disposed in the electrolytic solution tank; and a generator connected to the oxidation electrode and the reduction electrode. At least one of the oxidation electrode or the reduction electrode has a porous structure containing fine pores.

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.

The present disclosure describes solution methods for manufacturing perovskite halide films for use in solar cells. The methods include the use of additives that facilitate the formation of transitory, intermediate films that are later transformed into the final target perovskite halide films, such that the final films provide improved physical characteristics and operational performance.

An electrochernical cell comprises a first electrode having a first inner surface; a second electrode having a second inner surface, the second inner surface facing the first inner surface; a nanostructured material positioned on at least one of the first inner surface and second inner surface; and an ionic liquid positioned between the first inner surface and the second inner surface, the ionic liquid being in electrical communication with the first electrode and second electrode.

According to one embodiment, a photochemical reaction device includes: a solar cell; an electrolytic tank having a first tank storing a first solution including an oxidant and/or reductant of a redox medium and a second tank storing a second solution including water and/or proton; a first electrode set in the first tank, connected to a positive electrode of the solar cell through a first switching element, and connected to a negative electrode of the solar cell through a second switching element; and a second electrode set in the second tank, connected to the positive electrode of the solar cell through a third switching element, and connected to the negative electrode of the solar cell through a fourth switching element.

An electrochemical reaction device includes: an electrolytic solution tank including a first storage part storing a first electrolytic solution and a second storage part storing a second electrolytic solution; a reduction electrode immersed in the first electrolytic solution; and an oxidation electrode immersed in the second electrolytic solution. The second electrolytic solution contains a substance to be oxidized. The first electrolytic solution has a first liquid phase containing water and a second liquid phase containing an organic solvent and being in contact with the first liquid phase. At least one liquid phase of the first liquid phase or the second liquid phase contains a substance to be reduced and is in contact with the reduction electrode.