The present disclosure relates to the field of photovoltaic technologies. Disclosed are a solar cell and a photovoltaic module. The solar cell includes: an absorption layer; and an energy selective contact layer located on a surface of the absorption layer, the energy selective contact layer having selectivity for electron energy or hole energy, and the material of the energy selective contact layer including a low-dimensional perovskite material. According to the solar cell and the photovoltaic module provided by the present disclosure, a photovoltaic module can be manufactured.

A solar module for transforming solar energy into electrical energy includes a substrate and a pair of solar cells formed on the substrate next to each other and electrically connected in series to each other through a top common back electrode. A first solar cell of the pair has a pin configuration, and a second solar cell of the pair has a nip configuration. The pin configuration has hole and electron transport layers located in a reverse order relative to the nip configuration.

A semiconductor module has a layer structure and at least one capacitive sensor. The layer structure is formed with an upper electrode layer, a lower electrode layer, and an active layer arranged between the electrode layers. The active layer is made of a semiconductor material. The capacitive sensor has a measuring electrode which is integrated into the layer structure. There is also described a device which has such a semiconductor module and a method for producing such a semiconductor module.

A solar cell includes: a first electrode; a first hole transport layer containing nickel; an inorganic material layer containing titanium; a light-absorbing layer converting light into electric charge; and a second electrode. The first electrode, the first hole transport layer, the inorganic material layer, the light-absorbing layer, and the second electrode are layered in that order. The light-absorbing layer contains a perovskite compound represented by a formula AMX3, where A is a monovalent cation, M is a divalent cation, and X is a monovalent anion.

Aspects of the subject disclosure may include, for example, a redox battery system comprising a three dimensional array of a plurality of nano-batteries and a hydrogen power system comprising a nano-array of hydrogen paper, a heat source and a water source, wherein the hydrogen paper attracts hydrogen from the water source. Further embodiments can include a solar power system comprising an array of a plurality of nano-solar cells and an ionic diode power system comprising two electrodes separated by a polycarbonate membrane, two borophene electric charge capture devices, and a capacitor stack. Additional embodiment can include a power supply controller providing power to a linear amplifier using the redox battery system and causing recharging of the redox battery system utilizing the hydrogen power system, the solar power system, the ionic diode power system, or a combination thereof, to provide charge to the redox battery system. Other embodiments are disclosed.

An organic photodetector including an electron blocking layer, where the electron blocking layer prevents and/or reduces dark current by preventing electrons traveling from the organic photodetector's anode to the organic photodetector's photoactive layer during dark, photon-less conditions. The electron blocking layer is formed from a compound having the formula: [M].sup.a+[X].sub.a (General Formula (I)) where: M is a metal; X is CN, SCN, Se CN or TeCN; and a is at least 1.

Provided is a photoelectric conversion element including: a first electrode having opaqueness to light and formed of a metal; a hole blocking layer provided on the first electrode; an electron transport layer provided on the hole blocking layer; a hole transport layer provided on the electron transport layer; and a second electrode provided on the hole transport layer and having transmissivity to light, wherein the hole blocking layer contains an oxide of the metal in the first electrode.

Method of making an array of interconnected solar cells, including a) providing a continuous layer stack (1) of a prescribed thickness on a substrate (8), the layer stack (1) including an upper (2) and a lower (3) conductive layer having a photoactive layer (4) and a semiconducting electron transport layer (6) interposed there between; b) selectively removing the upper conductive layer (2) and the photoactive layer (4) for obtaining a contact hole (10) exposing the semiconducting electron transport layer (6); c) selectively heating the layer stack (1) to a first depth (d1) for obtaining a first heat affected zone (12) at a first center-to-center distance (s1) from the contact hole (10), the first heat affected zone (12) being transformed into a substantially insulating region with substantially the first depth (d1) in the layer stack, thereby locally providing an increased electrical resistivity to the layer stack (1).

According to an embodiment, a detection element includes a first electrode, a second electrode, an organic conversion layer, and a third electrode. The organic conversion layer is provided between the first electrode and the second electrode, and is configured to convert energy of a radiant ray into a charge. The third electrode is provided inside the organic conversion layer. Bias is applied to the third electrode.

According to an embodiment, a detection element includes a first electrode, a second electrode, an organic conversion layer, and a third electrode. A bias is applied to the first electrode. The organic conversion layer is arranged between the first electrode and the second electrode, and is configured to convert energy of a radiation into an electric charge. The third electrode is arranged in the organic conversion layer.