The present invention relates to a dye-sensitized solar cell unit (1) comprising a working electrode comprising a light-absorbing layer (10), a porous first conducting layer (12) for extracting photo-generated electrons from the light-absorbing layer (10), wherein the light-absorbing layer (10) is arranged on top of the first conducting layer (12), a porous insulating layer (105c) made of an insulating material, wherein the porous first conducting layer (12) is arranged on top of the porous insulating layer (105c). The dye-sensitized solar cell unit (1) further comprises a counter electrode comprising a second conducting layer (16) including conducting material, and a porous third conducting layer (106c) disposed between the porous insulating layer (105c) and the second conducting layer (16), and in electrical contact with the second conducting layer. The dye-sensitized solar cell unit (1) further comprises a liquid electrolyte for transferring charges between the counter electrode and the working electrode. The second conducting layer (16) is non-catalytic and the third conducting layer (106c) comprises catalytic particles (107) for improving the transfer of electrons to the liquid electrolyte.

A quantum dot sensitized solar cell (QDSSC) includes a highly catalytic Ni-doped CuS thin film as a counter electrode (CE). The Ni-doped CuS CE can deliver outstanding electrocatalytic activity, conductivity, and low-charge transfer resistance at the CE/electrolyte interface. As a result, the QDSSC can achieve higher efficiency (=4.36%) than a QDSSC with a bare CuS CE (3.24%).

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.

Disclosed is a bus stop using a large-scale perovskite solar cell in which a perovskite solar cell is prepared using a hybrid structure including a graphene-carbon nanotube. The bus stop includes a body unit fixed to the ground to maintain the overall shape, a solar cell unit for producing electrical energy from sunlight, and an energy storage system (ESS) for storing the electrical energy produced by the solar cell part.

A photoelectrode for a photoelectrochemical cell is disclosed. The photoelectrode comprises a back-contact solar cell comprising emitter and collector contacts being spaced apart by first openings. The emitter and collector contacts are respectively collected in an emitter busbar and a collector busbar. The photoelectrode further comprises a contact passivation layer to separate the emitter and collector contacts from the electrolyte when in use. The contact passivation layer further comprises second openings in correspondence with the first openings. The photoelectrode further comprises a resin layer covering the openings and a portion of the contact passivation layer such that in use only charge carriers from the emitter contacts traverse the contact passivation layer in its way to the electrolyte while charge carriers from the collector contacts are collected in the collector busbar. An electrocatalyst layer is further provided covering respectively the resin layer and/or the contact passivation layer.

A photoelectric conversion device of an embodiment includes: a first photoelectric conversion part including a first transparent electrode provided on a transparent substrate, a first active layer, and a first counter electrode; and a second photoelectric conversion part including a second transparent electrode, a second active layer, and a second counter electrode. A conductive layer containing noble metal as a main component is formed on a partial region of the second transparent electrode, and a fine particle layer having a stack of fine particles is formed on the conductive layer. The first counter electrode and the second transparent electrode are electrically connected by a connection part having a scribe groove penetrating through the fine particle layer from the second active layer and exposing a surface of the conductive layer, and a conductive layer having a part of the first counter electrode filled in the scribe groove.

The present invention relates to a solar cell and a method of producing the same. The solar cell comprises a porous light absorbing layer (1), a first porous conducting layer (2), a second conducting layer (3), a porous substrate (4) between the conducting layers, the porous substrate comprises a catalytic conducting portion (4a) in electrical contact with the second conducting layer and an insulating portion (4b) between the first porous conducting layer (2) and the conducting portion, and a conducting medium (5) for transporting charges between the conducting portion (4a) and the light absorbing layer (1). The conducting medium is located in the light absorbing layer (1), the first porous conducting layer (2), and partly the porous substrate (4) so that the insulating portion (4b) and a first part (4a) of the conducting portion (4a) comprises the conducting medium and a second part (4e) of the conducting portion is free of conducting medium.

Platinum films can be obtained by AACVD using a class of Pt-dialkyldithiocarbamates complexes, of the formula Pt(S.sub.2CNR.sub.2), wherein R is independently alkyl, such as isobutyl, aryl, or alkaryl, such as benzyl, particularly as single source precursors. The catalytic performance of the resulting Pt-films allows their use as counter electrodes in dye sensitized solar cells, for example. The efficiency of the AACVD-produced electrodes can be better than a conventionally used Pt-counter electrodes made by the doctor blade's method. The Pt(S.sub.2CNR.sub.2)-derived films have well connected and defect free surface topography and better catalytic performance, likely due to their high conductivity and reflectivity. A simple and low cost method employing such dithiocarbamate precursors can generate Pt-films and electrodes of broad applicability.

A simple, one-step method for producing a homogenous CeO.sub.2TiO.sub.2 composite thin film using aerosol-assisted chemical vapor deposition (CVD) of a solution containing triacetatocerium (III) and tetra isopropoxytitanium (IV) on a fluorine-doped tin oxide (FTO) substrate at a temperature ranging from about 500 to about 650 C. Methods for using the film produced by this method.

A photoelectric conversion device of an embodiment includes: a first photoelectric conversion part including a first transparent electrode provided on a transparent substrate, a first active layer, and a first counter electrode; and a second photoelectric conversion part including a second transparent electrode, a second active layer, and a second counter electrode. A conductive layer containing noble metal as a main component is formed on a partial region of the second transparent electrode, and a fine particle layer having a stack of fine particles is formed on the conductive layer. The first counter electrode and the second transparent electrode are electrically connected by a connection part having a scribe groove penetrating through the fine particle layer from the second active layer and exposing a surface of the conductive layer, and a conductive layer having a part of the first counter electrode filled in the scribe groove.