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.

The present invention relates to an inorganic perovskite quantum dot-based solar cell capable of providing a significantly excellent photoelectric conversion efficiency compared to the related art by increasing a light absorption capacity even though a photoactive layer has a limited thickness. Specifically, the inorganic perovskite solar cell may include: an electron transport layer that is disposed on a transparent electrode; a photoactive layer having a flat structure that is disposed on the electron transport layer and includes inorganic perovskite quantum dots; an organic hole transport layer that is disposed on the photoactive layer and includes nanopatterns; and a back electrode that is disposed on the organic hole transport layer.

A method for manufacturing a multi-cation perovskite layer, including: a) supply of a substrate having a deposition face, b) deposition of a precursor solution including precursors comprising CsX, FAY, PbZ.sub.2, with X, Y and Z = I, Br, and an FAC1 additive, the molar ratio of cesium to lead is between approximately 4 % and 22%, the molar ratio of FAC1 relative to lead between 0.1% and 5%, and the perovskite layer has an empirical formula of the type Cs.sub.xFA(.sub.1-x+w)Pb(I.sub.yBr(.sub.1-y)).sub.3 with x between 0.04 and 0.22, y between 0 and 1 and w between 0.001 and 0.05, c) sweeping of the wet film by an inert gas to crystallize the perovskite layer, and heat treatment so that the deposition face has a temperature ranging from about 25° C. to 80° C. C at least during step b).

An electrolytic capacitor comprises a case, a capacitor element mounted in the case and an element for controlling gas diffusion between inside and outside the case. The controlling element is embedded in the case.

Fabricating an electrode for use in a capacitor includes cutting an electrode precursor from a sheet of material. The electrode precursor is exposed to steam so as to form a steamed electrode precursor. A capacitor is fabricated and includes an electrode generated from the steamed electrode precursor.

The present invention relates to a slurry for forming a semiconductor electrode layer to obtain a dye-sensitized solar cell containing a porous layer, which is not susceptible to cracking and is capable of providing a higher conversion efficiency. The slurry for forming a semiconductor electrode layer contains two types of metal-oxide semiconductor particles having different particle sizes. When a semiconductor electrode layer is formed by coating and sintering such a slurry, cracking seldom occurs and a higher conversion efficiency is achieved when it is made into a film with a thickness of 3˜20 μm.

A simple, one-step method for producing a homogenous CeO.sub.2—TiO.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 capacitor is fabricated by generating a sheet of material that has a first active region that includes tunnels extending into an electrode metal. The sheet of material has a first inactive region that includes the electrode metal but does not include the tunnels extending into the electrode metal. The first inactive region has a first shape that includes multiple first projections that each projects from a perimeter of a circle. An electrode is removed from the sheet of material such that the electrode includes a portion of the inactive region. Additionally or alternately, fabricating a capacitor include using a first etching solution to etch a first sheet of material so as to generate a spent etchant. At least one chemical component is recovered from the spent etchant. A second etching solution is used to etch a second sheet of material. The second etchant includes at least one of the chemical components that was recovered from the spent etchant.

Disclosed here is a capacitive deionization device for removing ions from a target solution. The capacitive deionization device includes a first porous electrode, a second porous electrode, a first header plate, a second header plate, and a sealant. The second porous electrode is disposed below and spaced from the first porous electrode. The first header plate is disposed on the first porous electrode. The first header plate defines an input flow channel that is in fluidic communication with the first porous electrode. The second header plate is disposed below the second porous electrode. The second header plate defines an output flow channel that is in fluidic communication with the second porous electrode. The sealant is disposed between the first header plate and the second header plate and surrounds the first porous electrode and the second porous electrode.

Disclosed herein is a method comprising mixing an electroactive particle with a carbonaceous material to form a particle mixture that comprises a carbon coated particle; subjecting the carbon coated particle to a pulsed voltage between parallel plate electrodes or between rolls of a roll mill; and converting the carbon coated particle to a graphite coated particle via localized Joule heating. Disclosed herein too is an apparatus comprising a mixing device that is operative to mix an electroactive particle with a carbonaceous material to form a particle mixture that comprises a carbon coated particle; and a device for applying a pulsed voltage to the particle mixture; where the applying of the pulsed voltage is conducted when the particle mixture is located between opposing plate electrodes or between opposing rolls of a roll mill; where the device for applying the pulsed voltage converts the carbon coated particle into a graphite coated particle.