The present invention provides a light-transmitting electrode which has high electrical conductivity and high electron blocking performance. The present invention also provides a solar cell which is capable of achieving high energy conversion efficiency at low cost. The present invention provides a method for producing a light-transmitting electrode that has a light-transmitting substrate, a carbon nanotube film which is formed directly or indirectly on the light-transmitting substrate, and a metal oxide film which is formed directly on the carbon nanotube film. This production method includes vapor depositing the metal oxide film, which contains oxygen and a metal element belonging to the group 4, 5 or 6 of the periodic table, on one surface or both surfaces of the carbon nanotube film. The present invention provides a light-transmitting electrode which includes a light-transmitting substrate and a conductive carbon nanotube film that is formed directly or indirectly on the light-transmitting substrate.

Provided is a light receiving device including a transparent electrode and a method of manufacturing the light receiving device. A transparent electrode is formed so as to be in contact with a photoelectric conversion layer which absorbs light to generate electric energy, and the transparent electrode is formed by using a resistance change material which has high transmittance with respect to light in the entire wavelength range and of which resistance state is to be changed from a high resistance state into a low resistance state if a voltage exceeding a threshold voltage inherent in the resistance change material so that conducting filaments are formed in the transparent electrode. Accordingly, since the transparent electrode has high transmittance characteristic with respect to the light in the entire wavelength range and high conductivity characteristic, the light receiving device also has high photoelectric conversion efficiency and good electric characteristics.

Disclosed is a transparent electrode including a transparent substrate 100, conductive nanowires 10 forming networks, nanoparticles bonding the nanowires 10, and a conductive layer embedded in the transparent substrate 100.

A method of making a stack of the type comprising a first electrode, an active layer, and a second electrode, for use in an electronic device, in particular of the organic photodetector type or the organic solar cell type, the method comprising the following steps: a) depositing a first layer (2) of conductive material on a substrate (1) in order to form the first electrode; b) depositing an active layer (3) in the form of a thin organic semiconductor layer, this layer including non-continuous zones (30); c) locally eliminating the first conductive layer (2) through the non-continuous zones (30) of the active layer by chemical attack; and d) depositing a second layer (4) of conductive material on the active layer (3) in order to form the second conductive electrode.

A transparent electrode material including a conductive layer having an active surface and a second surface, and an adjacent base layer, wherein: ∘ the conductive layer includes a conductive network formed by metallic nanowires and carbon nanotubes encapsulated in a conductive material; ∘ the second surface of the conductive layer has encapsulated nanowires and/or nanotubes projecting therefrom; and ∘ the encapsulated nanowires and/or nanotubes projecting from the second surface of the conductive layer are embedded in the adjacent base layer; whereby the active surface of the conductive layer is smooth and electrically active, and the transparent electrode material has a sheet resistance less than 50 Ω/sq and a transparency greater than 70%.

The present disclosure relates to a semiconductor device comprising a first electrode, a second electrode, a third electrode, a fourth electrode, an insulating layer, and a nano-heterostructure. The nano-heterostructure comprises a first surface and a second surface. The first metallic carbon nanotube is located on the first surface and extends in a first direction. The semiconducting carbon nanotube is located on the first surface and extends in the first direction. The semiconducting carbon nanotube is parallel and spaced away from the first metallic carbon nanotube. The second metallic carbon nanotube is located on the second surface and extends in a second direction. An angle forms between the first direction and the second direction.

Various graphene-based photodetectors are disclosed. An example photodetector device may include: a substrate; a first antenna component fabricated on the substrate, the first antenna component comprising one or more antenna electrodes; a second antenna component fabricated on the substrate, the second antenna component comprising one or more antenna electrodes; a source region coupled to the first antenna component and the substrate; and a drain region coupled to the second antenna component and the substrate; wherein the one or more antenna electrodes in the first antenna component and the second antenna component are made of graphene.

This relates to a device for detecting or converting light or heat energy, the device comprising: a Graphene sheet formed into a scroll such as to provide a monolayer structure in which the radius of curvature of the graphene sheet increases on increasing distance from the longitudinal axis of the scroll.

A photodetector according to an embodiment of the present disclosure includes: a carbon allotrope electrode, wherein the carbon allotrope electrode has an average transmittance in a range from 85% to 95% at a wavelength in a range from 380 nm to 780 nm.

An ionic liquid (IL)-containing perovskite precursor composition includes perovskite precursors; and a salt of a cationic imidazole derivative in which at least one of the two nitrogen atoms in the imidazole ring is linked to a carbon chain bearing a cyano (—C≡N) group. A perovskite solar cell with high stability includes a layer constituted by a perovskite film formed using the perovskite precursor composition.