The present invention relates to a photovoltaic device (1). The device comprises a solar cell unit (2) comprising a porous light-absorbing layer (3) at a top side (2a), of a porous first conducting layer (4), a porous substrate (5) of an insulating material. The solar cell unit comprises a conducting medium. The photovoltaic device comprises a first conductor (7) in electrical contact with the first conducting layer (4), a second conductor (8) in electrical contact with the second conducting layer (6), and an encapsulation (9) encapsulating the solar cell unit. The encapsulation comprises a top sheet (9a) and a bottom sheet (9b). The first and second conductors (7, 8) are arranged between the encapsulation (9) and the solar cell unit (2) at the bottom side (2b) of the solar cell unit (2). The second conductor (8) is arranged between the second conducting layer (6) and the bottom sheet (9b) of the encapsulation (9), and the first conductor (7) is arranged between the porous substrate (5) and the bottom sheet (9b). The first conductor (7) is electrically insulated from the second conducting layer (6). A part (14) of the porous substrate (5) comprises conducting material (12) disposed between the first conductor (7) and the first conducting layer (4) to provide electrical contact between the first conductor and the first conducting layer.

A light harvesting supercapacitor and a method of preparing the light harvesting supercapacitor are disclosed. The light harvesting supercapacitor includes a transparent substrate, an active layer including TiO.sub.2 nanoparticles and polyaniline (PANI) nanoparticles disposed on the transparent substrate, an electrolyte layer including a solid separator and poly(2-acrylamido-2-methyl-1-propanesulfonic acid) disposed on the active layer, a carbon electrode disposed on the electrolyte layer; and a metal layer disposed on the activated carbon electrode. The method of preparing the light harvesting supercapacitor involves pulsed laser ablation in a liquid of bulk PANI to form the PANI nanoparticles. The light harvesting supercapacitor can be used in a photovoltaic device.

This application discloses a method, an apparatus, and a system for obtaining electronic layout applied to photovoltaic array in the field of equipment installation management. According to the method, the electronic device identifies each first area in a target picture to obtain position information and a module identifier of at least one photovoltaic module in each first area, and may directly obtain an electronic layout based on the position information and the module identifier of each photovoltaic module. In this way, a product identifier of each converter does not need to be manually obtained, and a photovoltaic module does not need to be manually added to the electronic layout. This reduces labor time consumption and improves efficiency of obtaining the electronic layout.

A solar cell module includes: a solar cell module body and a print layer formed further toward a light-receiving surface side than the solar cell module body by printing with specific transparency in a specific region. A rear surface side is visible from the light-receiving surface side in at least part of the specific region. The specific transparency is set to satisfy a condition that spectral sensitivity integral ratio A defined by formula (1) below is not less than a specific value A* that the spectral sensitivity integral ratio A takes when printing is performed with transparency resulting in a short circuit current ratio of 0.6. λ is wavelength (nm), f(λ) is quantum efficiency IPCE (%) in a case in which the print layer is formed, and f.sub.SC(λ) is quantum efficiency IPCE (%) in a case in which the print layer is not formed.

[00001]$\begin{array}{cc}A=\frac{{\int }_{360}^{830}\left(f\left(\lambda \right)\right)d\lambda }{{\int }_{360}^{830}\left(f_{\mathrm{SC}}\left(\lambda \right)\right)d\lambda }& \mathrm{Formula}\left(1\right)\end{array}$

An electrode connection structure is provided and includes a substrate, a first electrode, a second electrode, a semiconductor layer, a third electrode, and a conductive block. The first electrode and the second electrode are located on the substrate. The semiconductor layer is located on the first electrode and the second electrode. The third electrode is on the semiconductor layer. The conductive block penetrates through the semiconductor layer and the third electrode and directly contacts the second electrode and the third electrode. A first upper surface of the conductive block and a second upper surface of the third electrode are in different planes.

Described herein are non-stoichiometric perovskite ink solutions, comprising: a first composition of formula FA.sub.1-xCs.sub.xBX.sub.3; a second composition of CsX, FAX, REX.sub.3, or REX.sub.2; and one or more solvents; wherein x, X, RE, and B are as defined herein. Methods for preparing polycrystalline perovskite films using the non-stoichiometric ink solutions and the use of the films in large-size solar modules are additionally described.

A bifacial light-harvesting dye-sensitized solar cell is provided and has: a first transparent substrate, a second transparent substrate, a working electrode, a first semiconductor layer, a second semiconductor layer, a third semiconductor layer, a counter electrode, a light-transmitting catalyst layer, and a liquid electrolyte. A photoelectric conversion efficiency of the dye-sensitized solar cell is improved by using a specific working electrode structure.

An inspection method for a multilayer semiconductor device is provided. The inspection method can investigate multilayered ensembles of a multilayer semiconductor device and obtain stratigraphic thickness (ST) maps of each layer in the multilayer semiconductor device by utilizing absorption edges of materials of interests and obtaining calibration quality curves.

The present invention relates to a method for laminating solar cell modules comprising a plurality of solar cells electrically connected in series. The method comprises: providing a first and a second flexible substrate portion suitable for roll-to-roll deposition; providing a plurality of first electronic conductors on said first substrate portion and a plurality of second electrodes on said second substrate portion, wherein said plurality of first and second electrodes are provided as stripes spatially separated such that a plurality of gaps is formed; depositing an electronic conductor on one end of the first and second electrodes and depositing a continuous or discontinuous active layer on said plurality of first electrodes or said plurality of second electrodes, wherein said continuous or discontinuous active layer is an organic active layer; laminating by means of heat and pressure said first and said second substrate portions together in a roll-to-roll process such that the electronic conductors are brought into physical contact with the respective electronic conductor arranged on the opposite substrate, and that the active layer is brought into physical contact with the other one of said plurality first electrodes or said plurality of second electrodes and such that the active layer is brought into electrical contact with said plurality of first electrodes and said plurality of second electrodes. The plurality of first electrodes is arranged off-set relative said plurality of second electrodes such that each of said plurality of gaps between said plurality of second electrodes are partly or fully covered at least in one direction by respective one of said plurality of first electrodes. The present invention also relates to a solar cell module.

An integrated energy harvesting and storage device (IEHSD) includes a solar cell (SC) including an active layer between an optically transparent top electrode and a bottom electrode, and an energy storage device (SD) secured below the solar cell including a separator between a first electrode and a second electrode. The bottom electrode and the first or second electrode are electrically common with one another and are within a distance of ≤300 μm from one another.