Solar Cell Based on Copper (I) Oxide, and Cadmium Tin Oxide

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала.As a solar cell a heterostructure has been proposed that consists of an anode copper oxide Cu2O and a transparent conductive layer Cd—Sn—O obtained via extraction-pyrolytic method. The heterostructure is formed on a copper substrate by means of anodic oxidation with further applying a transparent conductive oxide film. An increase in the efficiency of the Cu2O/Cd–Sn–O element compared with Cu–Cu2O structure has been shown to be possible

The Application of Titanium Dioxide Coatings by the Extraction-Pyrolysis Method

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала

Solar Cell Based on Copper (I) Oxide, and Cadmium Tin Oxide

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала.As a solar cell a heterostructure has been proposed that consists of an anode copper oxide Cu2O and a transparent conductive layer Cd—Sn—O obtained via extraction-pyrolytic method. The heterostructure is formed on a copper substrate by means of anodic oxidation with further applying a transparent conductive oxide film. An increase in the efficiency of the Cu2O/Cd–Sn–O element compared with Cu–Cu2O structure has been shown to be possible

The Application of Titanium Dioxide Coatings by the Extraction-Pyrolysis Method

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала

Indium–tin oxide films obtained by extraction pyrolysis

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала.Thin indium–tin oxide (ITO) films were obtained by pyrolysis of solutions of indium and tin extracts on glass substrates. The extraction pyrolysis (EP) technology uses inexpensive starting compounds and provides the required stoichiometric ratio of elements due to complete mixing of precursors in the organic solution. The thermal decomposition of the extracts occurs in a narrow temperature range of 350– 400°C. X Ray photoelectron spectroscopy (XPS) studies showed that the ITO films obtained by extraction pyrolysis have no impurities including carbon. The films have a nanocrystalline structure with a grain size of ~6 nm according to XRD, AFM, and TEM studies. The optical transmission spectra showed that the films were highly transparent in the visible region of the spectrum and absorbed IR radiation at long and medium wavelengths

Indium–tin oxide films obtained by extraction pyrolysis

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала.Thin indium–tin oxide (ITO) films were obtained by pyrolysis of solutions of indium and tin extracts on glass substrates. The extraction pyrolysis (EP) technology uses inexpensive starting compounds and provides the required stoichiometric ratio of elements due to complete mixing of precursors in the organic solution. The thermal decomposition of the extracts occurs in a narrow temperature range of 350– 400°C. X Ray photoelectron spectroscopy (XPS) studies showed that the ITO films obtained by extraction pyrolysis have no impurities including carbon. The films have a nanocrystalline structure with a grain size of ~6 nm according to XRD, AFM, and TEM studies. The optical transmission spectra showed that the films were highly transparent in the visible region of the spectrum and absorbed IR radiation at long and medium wavelengths

Forming Porous Structures on Silicon with a Ferroelectric for Capacitive Microelectronic and Microsystems Engineering Elements

Текст статьи не публикуется в открытом доступе в соответствии с политикой журнала.The formation of heterostructures based on porous silicon with barium titanate for application in capacitive electronic and microsystem engineering elements has been experimentally investigated. The dependences of the capacitance and permittivity on the porous matrix dimensions, number of deposited barium titanate layers, and material of capacitor structure plates has been analyzed