Provided is a disclosure relating to a method for manufacturing an organic solar cell comprising providing a substrate; forming a first electrode on the substrate; forming a photoactive layer by coating a solution comprising a photoactive material and a solvent on the first electrode; drying the photoactive layer in a closed drying system having a constant volume; and forming a second electrode on the photoactive layer, and an organic solar cell manufactured using the same.

Provided is a method for manufacturing a display device. The method may comprise providing a substrate, providing a first organic solution which includes a mixed solvent containing a first solvent having a first boiling point and a second solvent having a second boiling point, conducting a first depressurized drying to form a second organic solution, and conducting a second depressurized drying to form a preliminary organic layer.

In a substrate pre-baking device, a baking box housing includes a baking chamber in an interior space of the baking box housing, wherein an opening corresponding to a side door is arranged on a lateral side of the baking box housing. The side door is arranged at the opening of the baking box housing. A heating structure is arranged in the baking chamber. A hot air curtain device is arranged at the side door of the baking box housing. When the side door is opened, the hot air curtain device is configured to form a hot air curtain for isolating the baking chamber from outside environment at the opening of the side door.

A method for manufacturing a light-emitting element, in particular, a method for manufacturing a light-emitting element with high emission efficiency is provided. In the method for manufacturing a light-emitting element that includes a light-emitting layer containing a host material and a light-emitting material that is an organic compound or an organic metal complex, the light-emitting layer is formed by co-evaporation of the light-emitting material and the host material, and the light-emitting layer is deposited by co-evaporation while the percentage of the partial pressure of carbon dioxide with respect to the total pressure in an evaporation chamber for the co-evaporation is kept higher than that in the air.

A method for producing an organic EL device having an anode, a cathode, at least one organic functional layer disposed between the anode and the cathode, and a sealing layer, comprising a step of forming the anode, a step of forming the cathode, a step of forming the at least one organic functional layer and a step of forming the sealing layer, wherein the average concentration: A (ppm) of a sulfur oxide to which the organic EL device during production is exposed from initiation time of the step of forming the at least one organic functional layer until termination time of the step of forming the sealing layer and the exposure time thereof: B (sec) satisfy the formula (1-1):
0AB<2.2(1-1).

A photoelectric conversion element according to an embodiment includes: a first electrode; a second electrode; and a photoelectric conversion layer that is in contact with the first electrode and the second electrode and includes an active layer containing a perovskite compound. The active layer gives an X-ray diffraction pattern having a first diffraction peak ascribed to the (004) plane of the perovskite compound and a second diffraction peak ascribed to the (220) plane of the perovskite compound. The ratio of the maximum intensity of the first diffraction peak to the maximum intensity of the second diffraction peak is 0.18 or more.

A method for producing an organic electronic device according to an embodiment includes: a device base formation step; a dehydration step of dehydrating a protective film-bearing sealing member under a pressure of 1000 Pa or more while conveying the protective film-bearing sealing member 10 in which a protective film 30 is laminated on a sealing member 20; and a sealing member bonding step of peeling off the protective film 30 from the protective film-bearing sealing member which has been subjected to the dehydration step and bonding the sealing member 20 to a device base. In the dehydration step, an atmosphere gas G1 having a dew point of 40 C. or lower is caused to flow from a downstream side to an upstream side in a conveyance direction of the protective film-bearing sealing member.

To provide an organic photoelectric conversion element, imaging device, and optical sensor having low dark currents, and a method of manufacturing a photoelectric conversion element. Provided is a photoelectric conversion element, including: a first electrode; an organic photoelectric conversion layer disposed in a layer upper than the first electrode, the organic photoelectric conversion layer including one or two or more organic semiconductor materials; a buffer layer disposed in a layer upper than the organic photoelectric conversion layer, the buffer layer including an amorphous inorganic material and having an energy level of 7.7 to 8.0 eV and a difference in a HOMO energy level from the organic photoelectric conversion layer of 2 eV or more; and a second electrode disposed in a layer upper than the buffer layer.

According to an embodiment, a producing method of a radiation detection element, includes: forming an organic semiconductor layer by applying an organic semiconductor solution onto a first conductive layer formed on a support substrate; forming a second conductive layer on the organic semiconductor layer; sealing a laminated body of the first conductive layer, the organic semiconductor layer, and the second conductive layer, formed on the support substrate, with a sealing member; and applying heat to the laminated body sealed with the sealing member. In at least one of forming of the organic layer and forming of the second conductive layer, a forming environment of the organic semiconductor layer and the second conductive layer are adjusted such that the solvent content of the organic semiconductor layer is in a predetermined range.

A method of manufacturing an organic electroluminescence display panel includes: forming pixel electrodes in matrix on a substrate; arranging column banks extending in column direction above the substrate along row direction, the banks each being between adjacent pixel electrodes in the row direction; applying ink containing organic light emitting material to gaps between adjacent banks, the applied ink being continuous in the column direction; reducing pressure of atmosphere including the substrate to first pressure while positioning a rectifying plate at first distance from upper surface of the substrate, the plate covering region with the ink applied on the substrate; reducing, after the reducing, the pressure to second pressure, which is lower than the first pressure, or lower while positioning the plate at second distance, which is greater than the first distance, from the surface; heating the substrate to form organic functional layer; and forming counter electrode above the functional layer.