A solar cell system and a flexible solar panel are disclosed herein. The solar cell system includes a glass housing, a set of rows of solar cells each defining a front side and a rear side and arranged within the glass housing. The solar cell system can also include a reflective element disposed in the glass housing and facing the rear side of the set of rows of solar cells and a first terminal coupled to a first end of the set of rows of solar cells, traversing through and sealed against the first end of the glass housing. The solar cell system can be configured with other solar cell systems into the flexible solar panel that is deployable in a wide range of potential applications.

A solar cell system and a flexible solar panel are disclosed herein. The solar cell system includes a glass housing, a set of rows of solar cells each defining a front side and a rear side and arranged within the glass housing. The solar cell system can also include a reflective element disposed in the glass housing and facing the rear side of the set of rows of solar cells and a first terminal coupled to a first end of the set of rows of solar cells, traversing through and sealed against the first end of the glass housing. The solar cell system can be configured with other solar cell systems into the flexible solar panel that is deployable in a wide range of potential applications.

The present invention provides a photoelectric conversion element having excellent heat resistance. In addition, the present invention provides an optical sensor and an imaging element including the photoelectric conversion element. In addition, the present invention provides a compound applied to the photoelectric conversion element. The photoelectric conversion element according to the embodiment of the present invention including a conductive film, a photoelectric conversion film, and a transparent conductive film, in this order, in which the photoelectric conversion film contains a compound represented by Formula (1) or (2). ##STR00001##

Embodiments include photoactive regions of organic photovoltaic cells including an n-type dopant or a mixture of n-type dopants, one or more electron donor materials, and one or more electron acceptor materials. Embodiments further include n-type dopants, photoactive regions of organic photovoltaics comprising n-type dopants, methods of preparing photoactive regions comprising n-type dopants, organic photovoltaics comprising n-type doped photoactive regions, and the like.

A first photoelectric conversion element according to an embodiment of the present disclosure includes: a first electrode; a second electrode that is disposed to be opposed to the first electrode; and a photoelectric conversion layer that is provided between the first electrode and the second electrode. The photoelectric conversion layer includes a fullerene C.sub.60 or a fullerene C.sub.70 as a first organic semiconductor material and a second organic semiconductor material having an ionization potential of 0 or more and 5.0 eV or less.

Provided is a multilayer imaging device capable of both securing a wide sensitive region and securing an accumulated amount of charges. An imaging device according to an embodiment comprises a pixel, the pixel including a photoelectric conversion layer (15); a first electrode (11) positioned close to a first surface of the photoelectric conversion layer and electrically connected to the photoelectric conversion layer; a second electrode (16) positioned on a second surface opposite to the first surface of the photoelectric conversion layer; a charge accumulation electrode (12) disposed close to the first surface of the photoelectric conversion layer and spaced apart from the first electrode in a direction parallel to the first surface; and a third electrode (200) disposed at a position to have a portion overlapping a gap between the first electrode and the charge accumulation electrode in a direction perpendicular to the first surface.

The present embodiments provide a transparent electrode having a laminate structure of: a metal oxide layer having an amorphous structure and electroconductivity, and a metal nanowire layer; and further comprising an auxiliary metal wiring. The auxiliary metal wiring covers a part of the metal nanowire layer or of the metal oxide layer, and is connected to the metal nanowire layer.

The present embodiments provide a transparent electrode having a laminate structure of: a metal oxide layer having an amorphous structure and electroconductivity, and a metal nanowire layer; and further comprising an auxiliary metal wiring. The auxiliary metal wiring covers a part of the metal nanowire layer or of the metal oxide layer, and is connected to the metal nanowire layer.

A solar cell includes a first substrate, a first hole transport layer, a first photoelectric conversion layer containing a perovskite compound, and a second photoelectric conversion layer containing a photoelectric conversion material in this order. A band gap of the perovskite compound is greater than a band gap of the photoelectric conversion material. With respect to an absorption wavelength of the first photoelectric conversion layer 3, a refractive index n.sub.A of the first hole transport layer 2 satisfies refractive index of the first substrate≤n.sub.A≤refractive index of the first photoelectric conversion layer. Further, with respect to a transmission wavelength of the first photoelectric conversion layer 3 and an absorption wavelength of the second photoelectric conversion layer 5, a refractive index n.sub.B of the first hole transport layer 2 satisfies refractive index of the first substrate≤n.sub.B≤refractive index of the first photoelectric conversion layer.

A perovskite-polymer composite comprising a perovskite and a polymer, wherein the polymer has a structural unit comprising a thiourea (—HN(C═S)NH—) fragment and a (—R.sup.1—O—R.sup.2—) fragment, wherein R.sup.1 and R.sup.2 are each independently a C.sub.1-C.sub.6 alkyl or a cycloalkyl linker; a mechanically robust and self-healable solar cell comprising same; and a method of making same.