Abstract: A hole injection layer and a second electrode are both formed to be continuous above a first electrode and above an auxiliary wiring. The hole injection layer contains a tungsten oxide. An UPS spectrum, obtained from a UPS measurement, has a protrusion appearing near a Fermi surface and within a region corresponding to a binding energy range lower than a top of a valence band, and the tungsten oxide satisfies a condition, determined from an XPS measurement, that a ratio in a number density of atoms other than tungsten atoms and oxygen atoms to the tungsten atoms does not exceed 0.83.

Abstract: The present invention is to provide an organic EL panel that is able to prevent the problems resulting from the unnecessary bank residues at a relatively low cost and has excellent light-emitting characteristics and a long life, and manufacturing method of the organic EL panel. Specifically, an organic EL element is obtained by forming organic EL elements by sequentially laminating an anode, a transparent conductive film, a hole-injection layer, a buffer layer, an organic light-emitting layer, a cathode, and a passivation layer on one surface of a substrate. Each bank residue positioned on the surface of the hole-injection layer has a diameter not greater than 0.2 ?m in one direction when the substrate is seen in plan view. Preferably, when the substrate is seen in plan view, the area of each bank residue is set to be not greater than 0.4 ?m2, or more preferably not greater than 0.04 ?m2.

Abstract: An organic EL display panel offering improved luminance includes: a substrate; pixel electrodes arranged in rows and columns; an insulating film coating the confronting edges of pixel electrodes adjacent in a column direction; banks each elongated in the column direction over a gap between pixel electrodes adjacent in the row direction; a hole transport layer in a gap between the banks; an organic light-emitting layer over the hole transport layer; and a common electrode over the organic light-emitting layer. Light is emitted from a first light-emitting portion and second light-emitting portions of the light-emitting layer. The first light-emitting portion is a portion above the pixel electrodes excluding where the insulating film is disposed. The second light-emitting portions are portions above both the pixel electrodes and the insulating film.

Abstract: The present invention provides an organic EL display panel and an organic EL display apparatus that can be driven at a low voltage and that exhibit excellent light-emitting efficiency. Sequentially fixated on a substrate are: a first electrode; auxiliary wiring; a hole injection layer; a functional layer; and a second electrode. The hole injection layer and the second electrode are both formed to be continuous above the first electrode and above the auxiliary wiring. The second electrode and the auxiliary wiring are electrically connected by the hole injection layer. The hole injection layer contains tungsten oxide and at least 2 nm thick so as to have, in an electronic state thereof, an occupied energy level in a range between 1.8 eV and 3.6 eV lower than a lowest energy level of a valence band in terms of a binding energy.

Abstract: A light-emitter including: a transparent first electrode; a charge injection transport layer; a light-emitting layer; and a transparent second electrode, layered in this order. The light-emitting layer is defined by a bank. The charge injection transport layer has a recessed structure including: an inner bottom surface in contact with a bottom surface of the light-emitting layer; and an inner side surface continuous with the inner bottom surface. The inner side surface includes: a lower edge continuous with the inner bottom surface; and an upper edge continuous with the lower edge. The upper edge is aligned with a bottom periphery of the bank, or has contact with a bottom surface of the bank. The charge injection transport layer has contact with a side surface of the light-emitting layer.

Abstract: An organic light-emitting display panel is provided that improves luminous efficiency and luminescent color by adjusting the difference in film thickness between layers of different luminescent colors, such as intermediate layers, when the intermediate layer and light-emitting layers are formed by a wet method. By varying the film thickness of an interlayer insulation film, which is a lower layer of an organic light-emitting element, the volume of a contact hole is varied by color, thereby adjusting the volume of a concavity in each anode plate. When ink that includes material for the intermediate layer, or like, is sprayed by an inkjet method, the film thickness of the intermediate layer, or like, changes in accordance with the amount of ink filing the concavity. Therefore, by adjusting the difference in volume between concavities of different colors, the difference in film thickness between the intermediate layers, or like, is finely adjusted.

Abstract: A device and method improving luminous efficiency and luminescent color in an organic EL display panel used in electronic devices such as televisions or the like by making it easy to adjust the difference in film thickness between layers of different luminescent colors, such as intermediate layers, when the intermediate layers and light-emitting layers are formed by a wet method. By varying by color the volume of a contact hole formed in an interlayer insulation film, which is a lower layer of an organic EL element, the volume of a concavity in each anode plate is adjusted. When ink that includes material for the intermediate layer or the like is sprayed by an inkjet method, the film thickness of the intermediate layer or the like changes in accordance with the amount of ink filing the concavity.

Abstract: A device manufacturing method including substrate preparation, pixel electrode formation, photosensitive film formation, first part exposure, second part exposure, and development. In first part exposure, after execution of photosensitive film formation, first photomask is arranged to face substrate and exposure is performed to cause first part of photosensitive film to be exposed to light via first photomask. In second part exposure, after or together with execution of first part exposure, second photomask is arranged to face substrate and exposure is performed to cause second part of photosensitive film, which is different from first part at least partially, to be exposed to light via second photomask. In second part exposure, second photomask is arranged such that end thereof overlaps with end of first photomask, and overlap between first and second photomasks positionally corresponds to electrical wire.

Abstract: An organic EL display panel includes a wiring layer, a planarizing film above the wiring layer, and a plurality of light-emitting cells in a row. A pair of first banks are above the planarizing film to delimit lateral surfaces of the light-emitting cells. The planarizing film includes a plurality of recesses that are each formed between adjacent ones of the light-emitting cells and extend between the first banks. A plurality of organic light-emitting layers are each in one of the light-emitting cells between the pair of first banks. A plurality of second banks are connected to the first banks, and each comprise a same material as the first banks. Each of the second banks is above one of the recesses and has a shape that conforms to a profile of the one of the recesses so that the second banks are lower in height than the first banks.

Abstract: An organic EL element includes a substrate and a light refractive layer, a first transparent electrode layer, an insulation layer, a hole transport layer, and a photosensitive resin layer stacked above the substrate. A luminous function layer is above the hole transport layer in a recess defined by the photosensitive resin layer. A second transparent electrode layer is above the luminous function layer. The light reflective layer, the first transparent electrode layer, the insulation layer, and the hole transport layer are formed above the substrate in a region isolated by the photosensitive resin layer. The photosensitive resin layer comprises a material that absorbs incident light of a predetermined wavelength. The first transparent electrode layer, the insulation layer, the hole transport layer, and the photosensitive resin layer each have a reflectance value that is between a local minimum value and a neighborhood value of the local minimum value.

Abstract: A light-emitter includes a first electrode and a layered body over the first electrode. The layered body includes a charge injection layer and a light-emitting layer. A bank defines a position of the light-emitting layer of the layered body, and a second electrode is over the layered body. The charge injection layer is formed by oxidation of an upper portion of a metal. The first electrode includes a metal layer that is a lower portion of the metal. An inner portion of the charge injection layer is depressed to define a recess. A portion of the bank is on an outer portion of the charge injection layer.

Abstract: A display panel, in which a plurality of drive units in a transistor array substrate include a faulty drive unit, and a plurality of pixel electrodes include a first pixel electrode corresponding to the faulty drive unit and a second drive unit corresponding to a non-faulty drive unit. A portion of the second pixel electrode is embedded in the corresponding contact hole, and is in contact with a power supply pad of the non-faulty drive unit, so that the second pixel electrode is electrically connected to the non-faulty drive unit. An insulator is inserted between the first pixel electrode and a power supply pad of the faulty drive unit, so that the first pixel electrode is electrically insulated from the faulty drive unit.

Abstract: A display panel apparatus has a structure which is less likely to seal a planarizing film even when an electrode plate is provided on the planarizing film, and the display panel apparatus includes: a planarizing film formed on a substrate; a pixel formed on the planarizing film and including: a lower electrode; an organic layer; and an upper electrode; an auxiliary electrode electrically insulated from the lower electrode and electrically connected to the upper electrode; a display section including a plurality of the pixels; an electrode plate electrically connected to the auxiliary electrode and arranged to cover the planarizing film outside the display section; and a power supply section electrically connected to the electrode plate, and the electrode plate has a hole exposing a part of a surface of the planarizing film.

Abstract: A light-emitting element that has an improved light-extraction efficiency and an improved color purity of an emitted light. A light-emitting element includes a reflective electrode, a transparent electrode, a light-emitting layer, a functional layer, and a color filter. An optical film thickness of the functional layer is from approximately 218 nm to approximately 238 nm for a light emitting element that emits a blue light. An optical film thickness of the functional layer is from approximately 384 nm to approximately 400 nm for a light emitting element that emits a red light.

Abstract: A display panel apparatus includes a planarizing film formed on a substrate, at least one pixel including a lower electrode; an organic EL layer; and an upper electrode which are formed above the planarizing film; an auxiliary electrode electrically connected to the upper electrode which is the opposite to the lower electrode; a display section including a plurality of the pixels; an electrode plate electrically connected to the auxiliary electrode and arranged to cover the planarizing film outside the display section, and the electrode plate has a hole exposing a part of a surface of the planarizing film. Furthermore, the display panel apparatus also includes a hole injection layer which is an inorganic material layer made of an inorganic material and covering the hole.

Abstract: A device and method improving luminous efficiency and luminescent color in an organic EL display panel used in electronic devices such as televisions or the like by making it easy to adjust the difference in film thickness between layers of different luminescent colors, such as intermediate layers, when the intermediate layers and light-emitting layers are formed by a wet method. By varying by color the volume of a contact hole formed in an interlayer insulation film, which is a lower layer of an organic EL element, the volume of a concavity in each anode plate is adjusted. When ink that includes material for the intermediate layer or the like is sprayed by an inkjet method, the film thickness of the intermediate layer or the like changes in accordance with the amount of ink filing the concavity.

Abstract: An organic EL display panel includes a wiring layer, a planarizing film above the wiring layer, and a plurality of light-emitting cells in a row. A pair of first banks are above the planarizing film to delimit lateral surfaces of the light-emitting cells. The planarizing film includes a plurality of recesses that are each formed between adjacent ones of the light-emitting cells and extend between the first banks. A plurality of organic light-emitting layers are each in one of the light-emitting cells between the pair of first banks. A plurality of second banks are connected to the first banks, and each comprise a same material as the first banks. Each of the second banks is above one of the recesses and has a shape that conforms to a profile of the one of the recesses so that the second banks are lower in height than the first banks.

Abstract: An organic light-emitting display panel is provided that improves luminous efficiency and luminescent color by adjusting the difference in film thickness between layers of different luminescent colors, such as intermediate layers, when the intermediate layer and light-emitting layers are formed by a wet method. By varying the film thickness of an interlayer insulation film, which is a lower layer of an organic light-emitting element, the volume of a contact hole is varied by color, thereby adjusting the volume of a concavity in each anode plate. When ink that includes material for the intermediate layer, or like, is sprayed by an inkjet method, the film thickness of the intermediate layer, or like, changes in accordance with the amount of ink filing the concavity. Therefore, by adjusting the difference in volume between concavities of different colors, the difference in film thickness between the intermediate layers, or like, is finely adjusted.

Abstract: A light emitter and a method of manufacturing a light emitter. The light emitter includes a first electrode, a charge injection transport layer, a light-emitting layer, and a second electrode that are layered in this order. At least the light-emitting layer is defined by a bank that has at least one liquid-repellent surface. The charge injection transport layer is principally composed of a metal compound that is more liquid-philic than the surface of the bank. The charge injection transport layer includes a recessed structure so that in a region defined by the bank, the charge injection transport layer is lower than a bottom surface of the bank.

Abstract: A light emitter and method for manufacturing a light emitter. The light emitter includes a first electrode, a charge injection transport layer, a light-emitting layer, and a second electrode that are layered in this order. At least the light-emitting layer is defined by bank. The charge injection transport layer includes a recessed portion having an inner bottom surface in contact with a bottom surface of the light-emitting layer and an inner side surface continuous with the inner bottom surface and in contact at least partly with a side surface of the light-emitting layer. The inner side surface has a lower edge continuous with the inner bottom surface, and an upper edge is aligned with a portion of a bottom periphery of the bank, the portion being in contact with the light-emitting layer or in contact with a bottom surface of the bank.