A stacked cell and preparation method thereof. The stacked cell includes: a crystalline silicon cell; a conductive connecting layer located on a surface of the crystalline silicon cell; a first isolation layer extending from a surface of the conductive connecting layer facing away from the crystalline silicon cell to penetrate through the conductive connecting layer, and a perovskite cell located on the surface of the conductive connecting layer facing away from the crystalline silicon cell.

A stacked cell and preparation method thereof. The stacked cell includes: a crystalline silicon cell; a conductive connecting layer located on a surface of the crystalline silicon cell; a first isolation layer extending from a surface of the conductive connecting layer facing away from the crystalline silicon cell to penetrate through the conductive connecting layer, and a perovskite cell located on the surface of the conductive connecting layer facing away from the crystalline silicon cell.

An imaging device is provided. The imaging device may include a substrate having a first photoelectric conversion unit and a second photoelectric conversion unit at a light-incident side of the substrate. The second photoelectric conversion unit may include a photoelectric conversion layer, a first electrode, a second electrode above the photoelectric conversion layer, a third electrode, and an insulating material between the third electrode and the photoelectric conversion layer, wherein a portion of the insulating material is between the first electrode and the third electrode.

The present inventive concept relates to a method of manufacturing a tandem solar cell, the method including: a step of preparing a perovskite solar cell, including a first conductive charge transporting layer, a light absorption layer, and a second conductive charge transporting layer, on a substrate; a step of forming a partition part in the perovskite solar cell to form a first perovskite unit solar cell and a second perovskite unit solar cell; a step of forming a contact part in the first perovskite unit solar cell to expose a certain region of the first perovskite unit solar cell; a step of forming a buffer layer in a top surface of each of the first perovskite unit solar cell and the second perovskite unit solar cell; a step of preparing a plurality of second solar cells; a step of bonding the plurality of second solar cells to the buffer layer to form a first unit tandem solar cell where the first perovskite unit solar cell, the buffer layer, and the second solar cell are sequentially stacked and a second unit tandem solar cell where the second perovskite unit solar cell, the buffer layer, and the second solar cell are sequentially stacked; and a step of electrically connecting the first unit tandem solar cell to the second unit tandem solar cell.

The present inventive concept relates to a method of manufacturing a tandem solar cell, the method including: a step of preparing a perovskite solar cell, including a first conductive charge transporting layer, a light absorption layer, and a second conductive charge transporting layer, on a substrate; a step of forming a partition part in the perovskite solar cell to form a first perovskite unit solar cell and a second perovskite unit solar cell; a step of forming a contact part in the first perovskite unit solar cell to expose a certain region of the first perovskite unit solar cell; a step of forming a buffer layer in a top surface of each of the first perovskite unit solar cell and the second perovskite unit solar cell; a step of preparing a plurality of second solar cells; a step of bonding the plurality of second solar cells to the buffer layer to form a first unit tandem solar cell where the first perovskite unit solar cell, the buffer layer, and the second solar cell are sequentially stacked and a second unit tandem solar cell where the second perovskite unit solar cell, the buffer layer, and the second solar cell are sequentially stacked; and a step of electrically connecting the first unit tandem solar cell to the second unit tandem solar cell.

Provided is a solid-state image pickup device that makes it possible to enhance image quality, and a manufacturing method thereof, and an electronic apparatus. A solid-state image pickup device includes a pixel section that includes a plurality of pixels, the pixels each including one or more organic photoelectric conversion sections, wherein the pixel section includes an effective pixel region and an optical black region, and the organic photoelectric conversion sections of the optical black region include a light-shielding film and a buffer film on a light-incidence side.

Provided is a solid-state image pickup device that makes it possible to enhance image quality, and a manufacturing method thereof, and an electronic apparatus. A solid-state image pickup device includes a pixel section that includes a plurality of pixels, the pixels each including one or more organic photoelectric conversion sections, wherein the pixel section includes an effective pixel region and an optical black region, and the organic photoelectric conversion sections of the optical black region include a light-shielding film and a buffer film on a light-incidence side.

A single solar battery device formed by a solid-state Li battery intrinsically stacked on a monolithic triple junction solar cell sharing the same electrode in between. The solar cell generates a voltage high enough to directly photo-charge a Li battery at the required C-rate without use of a converter. The subcells of the monolithic triple junction solar cell are connected monolithically in series via optimized tunnel recombination junctions through which electrons and holes from the connected subcells can recombine. The intrinsic integration of the battery with solar cell enables using of a single device without an external cable connection, thus facilitating and decreasing the installation cost.

A tandem photovoltaic structure including, from the rear face to the front face: a first SHJ solar cell comprising a first layer of P-type doped amorphous silicon and a substrate of N-type doped crystalline silicon, a junction layer, a second perovskite-type solar cell comprising an active layer and a second P-type layer, the junction layer being made of N-type TCO and being in direct contact either with the second P-type layer or with the first P-type layer, one amongst the first or second solar cell also comprising an N-type layer, the junction layer serving as an N-type layer in the other one amongst the first or second solar cell.

A tandem photovoltaic structure including, from the rear face to the front face: a first SHJ solar cell comprising a first layer of P-type doped amorphous silicon and a substrate of N-type doped crystalline silicon, a junction layer, a second perovskite-type solar cell comprising an active layer and a second P-type layer, the junction layer being made of N-type TCO and being in direct contact either with the second P-type layer or with the first P-type layer, one amongst the first or second solar cell also comprising an N-type layer, the junction layer serving as an N-type layer in the other one amongst the first or second solar cell.