Provided are compounds having a first ligand L.sub.A of

##STR00001##

that are useful in OLEDs as emitters.

The present invention provides a thermally activated delayed fluorescent material, a method for preparing the same, and an electroluminescent device including a compound consisting of a receptor A and a donor D, the compound having a molecular structure of D-A shown in Formula 1:

D-A Formula 1 wherein the receptor A is selected from any one of the following structural formulas:

##STR00001## wherein R is selected from any one of the following structural formulas:

##STR00002## ##STR00003##

and the donor D is selected from any one of the following structural formulas:

##STR00004## ##STR00005##

Provided are a method for manufacturing an electronic device capable of efficiently utilizing a material and a method for removing impurities using the same. The method for manufacturing an electronic device comprises the steps of: placing a transfer film on a plurality of functional layers which are positioned apart from each other on a source substrate; bringing a first transfer target into close contact with the lower surface of the transfer film by applying pressure to a portion of the transfer film that corresponds to the first transfer target from among the plurality of functional layers by using a probe; separating the transfer film from the source substrate in a state in which the first transfer target is in close contact with the lower surface; placing the transfer film on a target substrate in the state in which the first transfer target is in close contact with the lower surface; placing the first transfer target on the target substrate by applying pressure to a portion of the transfer film that corresponds to the first transfer target; and separating the transfer film from the target substrate in a state in which the first transfer target is positioned on the target surface.

Described is an active layer having a first surface region and a bulk region, the active layer comprising a small molecule component and a polymer component, wherein the relative concentration of the small molecule component is lower in the first surface than in the bulk region. Also described is a method of producing a surface-modified active layer comprising the steps of providing a pristine active layer comprising a small molecule component and a polymer component; applying an adhesive to the exposed surface of the pristine active layer to produce an adhesive-bound active layer; and removing the adhesive from the adhesive-bound active layer, and a method of producing electrical energy from sunlight, such as sunlight deposited over bodies of water.

An electronically pure carbon nanotube ink, includes a population of semiconducting carbon nanotubes suspended in a liquid, the ink being essentially free of metallic impurities and organic material, and characterized in that when incorporated as a carbon nanotube network in a metal/carbon nanotube network/metal double diode, a nonlinear current-bias curve is obtained on application of a potential from 0.01 V to 100 V. The ink can be used to prepare air-stable n-type thin film transistors having performances similar to current thin film transistors used in flat panel displays amorphous silicon devices and high performance p-type thin film transistors with high- dielectrics.

A method for producing a liquid composition formed of a phosphorescent material and an organic solvent includes the steps of: dissolving a phosphorescent material in an organic solvent to prepare a mixed liquid, and filtering the mixed liquid by a filtering device. The filtering device is a housing or holder, a fluororesin membrane filter, and a filter support member. A material of a portion of the housing and holder in contact with the mixed liquid is a metal or a mixture of metal and at least one of glass, fluororesins, polyethylene not containing a phosphorus antioxidant, and polyethylene not containing an oxidized phosphorus antioxidant. A material of a portion of the filter support member in contact with the mixed liquid is at least one of metals, glass, fluororesins, polyethylene not containing a phosphorus antioxidant, and polyethylene not containing an oxidized phosphorus antioxidant.

A composition is provided in which a phosphorescent compound represented by formula (1) and a host material are blended with each other. The amount of chlorine atoms contained as impurities in the phosphorescent compound is 3.5 ppm by mass or less with respect to the total amount of solid contents blended in the composition.

##STR00001##

In Formula (1), M.sup.1 represents an iridium atom; n.sup.1 represents an integer of 1 or more, n.sup.2 represents an integer of 0 or more, n.sup.1+n.sup.2 is 2 or 3; E.sup.1 and E.sup.2 represent a carbon atom or a nitrogen atom; R.sup.1 ring represents a 5-membered aromatic heterocyclic ring and R.sup.2 ring represents an aromatic hydrocarbon ring; A.sup.1-G.sup.1-A.sup.2 represents an anionic bidentate ligand; A.sup.1 and A.sup.2 represent a nitrogen atom; and G.sup.1 represents a single bond.

The present invention provides a green light thermal activation delayed fluorescent material, a synthesizing method thereof, and an electroluminescent device. The green light thermal activation delayed fluorescent material is a target compound having a molecular structure of D-A and synthesized by a reaction of an electron donor and an electron acceptor, wherein the electron acceptor being a planar electron acceptor in an ultra-low triplet energy state, and a triplet energy state of the target compound ranging from 2.0 to 3.0 eV. The method for synthesizing a green light thermal activation delayed fluorescent material includes the following steps: a reaction solution preparation step; a target compound synthesis step; an extraction step; and a target compound purification step. The electroluminescent device includes: a substrate layer; a hole transporting and injecting layer; a light emitting layer; an electron transporting layer; and a cathode layer.

A composition contains an organic compound and an anthracene compound different from the organic compound, the anthracene compound having a hydrogen atom at at least one of positions 9 and 10, in which the concentration of the anthracene compound is 100 ppm or less. Additionally, a long-lived organic light-emitting device includes an organic compound layer containing a reduced concentration of the anthracene compound.

A method for producing the photoelectric conversion element includes, in carbon nanotubes including semiconducting carbon nanotubes having different chiralities from each other and metallic carbon nanotubes, changing a chirality distribution in the semiconducting carbon nanotubes, separating the carbon nanotubes into the semiconducting carbon nanotubes and the metallic carbon nanotubes after changing the chirality distribution, covering the semiconducting carbon nanotubes with a polymer after performing separating, and forming a photoelectric conversion film including the semiconducting carbon nanotubes between a pair of electrodes after performing covering with the polymer.