A photoelectric conversion device includes: a substrate; a first photoelectric conversion element including a first substrate electrode, a first photoelectric conversion layer, and a first counter electrode; a second photoelectric conversion element including a second substrate electrode, a second photoelectric conversion layer, and a second counter electrode; and a connection including a groove, a conductive portion and a conductive layer, the conductive portion being provided in the groove and including a part of the first counter electrode, and the conductive portion and the conductive layer electrically connecting the first counter electrode and the second substrate electrode. The conductive layer overlaps the first counter electrode on an edge of the groove, and a total thickness of the conductive portion and the conductive layer is larger than a thickness of the first counter electrode.

A photoelectric conversion device includes: a substrate; a first photoelectric conversion element including a first substrate electrode, a first photoelectric conversion layer, and a first counter electrode; a second photoelectric conversion element including a second substrate electrode, a second photoelectric conversion layer, and a second counter electrode; and a connection including a groove, a conductive portion and a conductive layer, the conductive portion being provided in the groove and including a part of the first counter electrode, and the conductive portion and the conductive layer electrically connecting the first counter electrode and the second substrate electrode. The conductive layer overlaps the first counter electrode on an edge of the groove, and a total thickness of the conductive portion and the conductive layer is larger than a thickness of the first counter electrode.

Embodiments of the present application provide an array substrate, a fabrication method for an array substrate, and a display panel. The array substrate includes a substrate, a gate, a gate insulating layer, a seed layer, and a semiconductor layer that are sequentially stacked. A surface of the semiconductor layer away from the seed layer has a concave-convex structure formed by growth of nanocrystalline grains, which enhances light absorption of the semiconductor layer and solves the problems of poor light sensitivity and slow response speed of semiconductor devices.

A tandem photovoltaic device includes: a tunnel junction between an upper cell unit and a lower cell unit. The lower cell unit is a crystalline silicon cell. The tunnel junction includes: a carrier transport layer, a crystalline silicon layer, and an intermediate layer located between the carrier transport layer and the crystalline silicon layer. The carrier transport layer is a metal oxide layer. The intermediate layer includes a tunneling layer. The crystalline silicon layer has a doping concentration greater than or equal to 10.sup.17 cm.sup.−3. The carrier transport layer is in direct contact with a shadow surface of the upper cell unit. If the crystalline silicon layer is a p-type crystalline silicon layer, a first energy level is close to a second energy level. If the crystalline silicon layer is an n-type crystalline silicon layer, a third energy level is close to a fourth energy level.

A photoexcitation material includes: a wurtzite type solid solution crystal containing gallium, zinc, nitrogen and oxygen, wherein a peak (A) of an existence ratio of nitrogen or oxygen which is a first adjacent atom of the gallium or zinc and a peak (B) of an existence ratio of gallium or zinc which is a second adjacent atom of the gallium or zinc satisfy a relational expression of A>B in a relationship between a distance and the existence ratio of the adjacent atom of the gallium or zinc, the relationship being obtained from an extended X-ray absorption fine structure analysis.

A photoexcitation material includes: a wurtzite type solid solution crystal containing gallium, zinc, nitrogen and oxygen, wherein a peak (A) of an existence ratio of nitrogen or oxygen which is a first adjacent atom of the gallium or zinc and a peak (B) of an existence ratio of gallium or zinc which is a second adjacent atom of the gallium or zinc satisfy a relational expression of A>B in a relationship between a distance and the existence ratio of the adjacent atom of the gallium or zinc, the relationship being obtained from an extended X-ray absorption fine structure analysis.

A structure including quantum dots formed in a surface control region, a method of forming a structure including quantum dots in a surface control region, a surface-controlled substrate provided with the structure including quantum dots, and a photoelectronic element using the same. The method includes forming multiple surface control layers that differ in etch resistance on a substrate, securing a surface control region on the substrate by forming control patterns having respectively different sizes in the respective surface control layers depending on the etch resistance values through an exposure process, forming the structure including quantum dots in the surface control region by using the plurality of surface control layers as masks, and removing the surface control layers.

A structural body that includes a film that has a phase-separated nanostructure where a separate columnar shape phase is dispersed in a matrix phase that are phase-separated in a state of thermal equilibrium. The matrix phase is formed from any one of a p-type semiconductor material and an n-type semiconductor material, and the separate columnar shape phase is formed from the other semiconductor material. The film is formed on a substrate such that the separate columnar shaped phase and the matrix phase have three-dimensional junction planes.

A photosensitive device substrate including a substrate, an active device, and a photosensitive device is provided. The active device and the photosensitive device are disposed on the substrate. The active device has a semiconductor pattern and a gate electrode. The semiconductor pattern is disposed between the substrate and the gate electrode. The photosensitive device is electrically connected to the active device. The photosensitive device has a photoelectric conversion layer and a first electrode and second electrode disposed on two opposite sides of the photoelectric conversion layer. The first electrode is located between the photoelectric conversion layer and the semiconductor pattern, and the material of the first electrode includes a metal oxide.

A photosensitive device substrate including a substrate, an active device, and a photosensitive device is provided. The active device and the photosensitive device are disposed on the substrate. The active device has a semiconductor pattern and a gate electrode. The semiconductor pattern is disposed between the substrate and the gate electrode. The photosensitive device is electrically connected to the active device. The photosensitive device has a photoelectric conversion layer and a first electrode and second electrode disposed on two opposite sides of the photoelectric conversion layer. The first electrode is located between the photoelectric conversion layer and the semiconductor pattern, and the material of the first electrode includes a metal oxide.