A plurality of light-emitting devices (10) include a plurality of light-emitting devices (10a), a plurality of light-emitting devices (10b), and a plurality of light-emitting devices (10c). The plurality of light-emitting devices (10) are aligned on a reflecting member (20). Six light-emitting devices (10c) are aligned in a straight line along one direction. Four light-emitting devices (10b) are aligned surrounding a region facing one ends of the six light-emitting devices (10c). Each of four light-emitting devices (10a) are aligned with each of the four light-emitting devices (10b) outside the four light-emitting devices (10b).

A display device of the present disclosure includes a pixel region including a pixel including a light emitting unit arranged on a substrate, and, in the pixel region, an anode electrode of the light emitting unit is provided with a region including a pixel inclined with respect to a substrate surface. Then, an electrode surface of the anode electrode has an inclination angle according to a surface shape of a base insulating layer. An electronic device of the present disclosure includes the display device having the configuration described above.

A display unit is provided with a plurality of pixels that are two-dimensionally arranged and each include an organic electroluminescence element emitting light of one of a plurality of colors. The pixels are arranged along one direction for each of light emission colors. The pixels each include a first insulating film, a second insulating film, and an organic layer. The first insulating film has openings for the respective pixels. The second insulating film extends along the arrangement direction for each of the light emission colors, in a region between pixels of different light emission colors, out of the plurality of pixels, on the first insulating film. The organic layer is formed in each of the openings, and includes a light-emitting layer. The first insulating film includes a recess that connects together the openings of pixels of the same light emission color, out of the plurality of pixels.

A light-emitting device (20) includes a first light-emitting member (10a) and a second light-emitting member (10b). Each of the first light-emitting member (10a) and the second light-emitting member (10b) includes a first surface (12) and a second surface (14), and light is emitted from the first surface (12). The first light-emitting member (10a) includes a first region (16a) and a second region (16b), the first region (16a) of the first light-emitting member (10a) being located on the second surface (14) side of the second light-emitting member (10b) and the second region (16b) of the first light-emitting member (10a) being located on the first surface (12) side of the second light-emitting member (10b).

A plurality of light-emitting devices (10) include a plurality of light-emitting devices (10a), a plurality of light-emitting devices (10b), and a plurality of light-emitting devices (10c). The plurality of light-emitting devices (10) are aligned on a reflecting member (20). Six light-emitting devices (10c) are aligned in a straight line along one direction. Four light-emitting devices (10b) are aligned surrounding a region facing one ends of the six light-emitting devices (10c). Each of four light-emitting devices (10a) are aligned with each of the four light-emitting devices (10b) outside the four light-emitting devices (10b).

A novel light-emitting device that is highly convenient, useful, or reliable is provided. A novel functional panel that is highly convenient, useful, or reliable is provided. The light-emitting device includes an insulating film, a group of structure bodies, a layer containing a light-emitting material, a first electrode, and a second electrode. The group of structure bodies includes a structure body and a different structure body, a first distance is provided between the different structure body and the structure body, the insulating film includes a first surface, the structure body includes a sidewall, the sidewall forms a first angle with the first surface, and the first angle is greater than 0° and less than or equal to 90°. The layer containing a light-emitting material includes a first region and a second region, the first region is interposed between the second electrode and the first electrode, light is emitted from the first region, the second region is interposed between the second electrode and the sidewall, and the sidewall reflects light. The first electrode includes a third region, and the third region is interposed between the first region and the first surface.

Display devices and electronic devices are disclosed. In one example, a display device includes lower electrodes arrayed in a matrix on a substrate; partition walls between adjacent ones of the lower electrodes; an organic layer formed by stacking material layers on an entire surface including upper surfaces of the lower electrodes and upper surfaces of the partition walls; and an upper electrode formed on an entire surface including an upper surface of the organic layer. In pixels with a light emitting unit in which the lower electrodes, the organic layer, and the upper electrode are stacked, light in a predetermined band is extracted to the outside by a resonator structure formed between the lower electrode and the upper electrode, and light in a band different from the predetermined band is extracted to the outside by total reflection at an interface between the organic layer and the partition wall.

A light distribution of light from a light-emitting device (10) has a higher luminous intensity in a first direction (D1) compared to a reference direction (R), the first direction (D1) being different from the reference direction (R). The reference direction (R) is a center direction of the light distribution, for example, a direction along the thickness direction of a substrate (100), a direction along the width direction of each layer (for example, an EML (126)) of a resonator (150), or a normal direction of a second surface (104) of the substrate (100). In addition, the light distribution has a higher luminous intensity in a second direction (D2) compared to the reference direction (R), the second direction (D2) being on an opposite side of the first direction (D1) with respect to the reference direction (R).

A light distribution of light from a light-emitting device (10) has a higher luminous intensity in a first direction (D1) compared to a reference direction (R), the first direction (D1) being different from the reference direction (R). The reference direction (R) is a center direction of the light distribution, for example, a direction along the thickness direction of a substrate (100), a direction along the width direction of each layer (for example, an EML (126)) of a resonator (150), or a normal direction of a second surface (104) of the substrate (100). In addition, the light distribution has a higher luminous intensity in a second direction (D2) compared to the reference direction (R), the second direction (D2) being on an opposite side of the first direction (D1) with respect to the reference direction (R).

A display device includes a plurality of pixels each including a first light emitting element with a first light reflecting layer, a second light emitting element with a second light reflecting layer, and a third light emitting element with a third light reflecting layer, arranged in a two-dimensional matrix. Each of the light emitting elements includes a first electrode, an organic layer, and a second electrode. Grooves that each have a light shielding layer are formed in a boundary region between the light emitting elements. A bottom of the first groove and a bottom of the third groove are located at a position higher than a top surface of the first light reflecting layer. A bottom of the second groove is located at a position higher than a top surface of the second light reflecting layer.