The present application provides a film preparation method, a solar cell, a photovoltaic device, and a photovoltaic system. The film preparation method includes forming a first passivation layer on a first surface of a substrate by using a first preparation technique; and forming a second passivation layer on a surface of the first passivation layer away from the substrate by using a second preparation technique, a material of the second passivation layer is the same as that of the first passivation layer; wherein a passivation layer forming speed of the first preparation technique is lower than that of the second preparation technique, and a passivation effect of the first passivation layer is better than that of the second passivation layer.

A solar cell and a manufacturing method thereof, and a photovoltaic system. The solar cell includes: a substrate layer including a first surface and a second surface arranged oppositely along a thickness direction thereof; a tunnel oxide layer, a first doped polysilicon layer, and a first passivation layer sequentially arranged on the first surface of the substrate layer in a direction gradually away from the substrate layer; and a first finger electrode layer, at least one of the first fingers being arranged in first connection holes, bottoms of the first connection holes being located in the first doped polysilicon layer, and the first fingers passing through the first connection holes corresponding thereto to be electrically connected to the first doped polysilicon layer; and in the first direction, widths of the first connection holes being all less than widths of the first fingers corresponding to the first connection holes. While ensuring good electrical connection, the solar cell causes less damage and recombination to a passivation structure of the solar cell, and has high photoelectric conversion efficiency.

Method of manufacturing a solar cell, comprising: providing a solar cell (100) having an active surface (105a) intended, in use, to be exposed to sunlight; forming, in correspondence of said active surface, a protection against low-energy protons and other radiations harmful to the solar cell. Forming a protection comprises forming a layer of resin (110; 210) and forming by deposition of material on the resin layer a layer of protective material (115; 215b) on top of the resin layer.

The present disclosure provides a back-contact solar cell, a fabrication method, and a solar-cell assembly. In one aspect, a back-contact solar cell includes a solar-cell body and an isolating groove. The solar-cell body includes a silicon substrate, a first semiconductor layer in a first region of a back surface of the silicon substrate, a second semiconductor layer having a portion in a second region of the back surface, and a transparent conductive film layer stacked on the first and second semiconductor layers. The isolating groove extends through the second semiconductor layer and the transparent conductive film layer. An area of a cross section of the isolating groove decreases towards the silicon substrate, and the cross section is parallel to the silicon substrate.

Provided is an optical module including a substrate, a light emitting element on the substrate, a light receiving element on the substrate, a first casing on the substrate and surrounds a periphery of the light emitting element, and a second casing on the substrate and surrounds a periphery of the light receiving element. Furthermore, the optical module includes a light emitting lens in the first casing on an optical axis of the light emitting element and a light receiving lens in the second casing on an optical axis of the light receiving element, in which a first diameter of one lens out of the light emitting lens and the light receiving lens in a first direction toward an optical axis of the other lens with reference to an optical axis of the one lens is shorter than a second diameter of the one lens in a second direction.

Device (1) for characterizing a substance (2) capable of emitting a photoluminescence radiation (Rp) in a first spectral range, the device (1) comprising: an electroluminescent component (3), at least semi-transparent in the first spectral range, and comprising first and second opposite surfaces (30, 31), the electroluminescent component (3) being suitable for emitting an excitation radiation (Re.sub.1) outgoing from the first surface (30), emitted in a first spectral range according to a circular polarization state; the excitation radiation (Re.sub.1) outgoing from the first surface (30) being able to pass through the electroluminescent component (3), after being reflected, and exit from the second surface (31); a polarization filter (4), arranged to filter the excitation radiation (Re.sub.2) outgoing from the second surface (31), and suitable for modifying the circular polarization state so as to obtain an extinguishing of the excitation radiation (Re.sub.2) outgoing from the second surface (31) of the electroluminescent component (3); a detector (5), arranged to detect the photoluminescence radiation (Rp) outgoing from the polarization filter (4).

The present disclosure provides a solar cell and a preparation method thereof, belongs to the technical field of solar cells. The preparation method of a solar cell according to the present disclosure includes: forming a passivation structure on a contact silicon layer at a back side of a silicon substrate; where the back side is a side opposite to a light incident side; removing the passivation structure located at least part of an electrode region by laser to form a contact opening, melting at least part of the contact silicon layer at the contact opening by laser, and solidifying the molten contact silicon layer to form a re-solidified structure; where the electrode region is a region configured to form a back electrode; and electroplating to form a back electrode in the electrode region on the back side of the contact silicon layer.

The method for preparing a solar cell includes providing a substrate having a first surface and a second surface opposite to the first surface; forming a doped layer and a first passivation layer stacked sequentially in a direction away from the substrate on the first surface; forming a second passivation layer on the second surface; forming multiple first grid line electrodes arranged at intervals on the surface of the first passivation layer away from the substrate, and forming multiple second grid line electrodes arranged at intervals on the surface of the second passivation layer away from the substrate; performing a laser processing on the multiple first grid line electrodes and an adjacent region of the multiple first grid line electrodes, and applying a reverse current between the multiple first grid line electrodes and the multiple second grid line electrodes.

A surface composite film structure with longitudinal transmission cutoff and transverse transmission conduction, and a preparation method and application thereof are provided. The surface composite film structure includes a nano dielectric layer arranged on a surface of a silicon substrate, a silicide layer arranged on the nano dielectric layer and a polycrystalline silicon layer arranged on the silicide layer. A material of the nano dielectric layer is a hydrogenated silicon oxide film, a material of the silicide layer is a hydrogenated carbon nitride silicon film including phosphorus or boron, and a material of the polycrystalline silicon layer is a phosphorus-doped or boron-doped polycrystalline silicon film. The surface composite film structure can achieve an excellent passivation effect and has the characteristics of longitudinal non-conduction and transverse conduction, and the transverse sheet resistance is flexibly adjustable, meeting the performance requirements of new silicon-based semiconductor physical devices.

A responsive faade system is configured to control the transmission of light from a first side of the responsive faade system to a second side of the responsive faade system in response to inputs from one or more light sensors. The responsive faade system includes a drive system, a plurality of panels driven by the drive system, and a control system. The control system is configured to send drive signals to the drive system to rotate the plurality of panels to selectively block the amount of light passing from the first side of the responsive faade system to the second side of the responsive faade system. In some applications, the light sensors are configured to measure real-time sunlight data such that the control system can instruct the drive system to rotate one or more of the plurality of panels into a position based on the real-time sunlight data.