Nombre del producto:Tetrakis(triphenylphosphine)palladium(0)

IUPAC Name:tetrakis(triphenylphosphine)palladium(0)

CAS:14221-01-3
Fórmula molecular:C72H60P4Pd
Pureza:98%
Número de catálogo:CM100928
Peso molecular:1155.59

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CM100928-25g in stock ǕǕǕ

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Detalles del producto

Núm. De CAS :14221-01-3
Fórmula molecular:C72H60P4Pd
Punto de fusión:-
Código de sonrisas:C=1C=CC(=CC1)[P](C=2C=CC=CC2)(C=3C=CC=CC3)[Pd]([P](C=4C=CC=CC4)(C=5C=CC=CC5)C=6C=CC=CC6)([P](C=7C=CC=CC7)(C=8C=CC=CC8)C=9C=CC=CC9)[P](C=%10C=CC=CC%10)(C=%11C=CC=CC%11)C=%12C=CC=CC%12
Densidad:
Número de catálogo:CM100928
Peso molecular:1155.59
Punto de ebullición:
Nº Mdl:MFCD00010012
Almacenamiento:Keep in a tight container filled with nitrogen and store at 2°C~8°C

Category Infos

Catalysts and Ligands
A catalyst refers to a substance that increases the rate of a reaction without changing the overall standard Gibbs free energy change of the reaction. Ligands represent atoms, molecules, and ions that can bond with a central atom (metal or metalloid). In general, ligands will donate at least one electron when participating in a bond. Two-phase catalysis of catalysts and ligands is the first application in the field of fluorine chemistry. The method of self-fluorine two-phase catalysis has developed rapidly, and a large number of new fluorine-based catalysts and ligands (especially phosphines) have been obtained in the field of chemistry.
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Organic Photodiode (OPD)
The most common type of organic photodetector is the organic photodiode (OPD). The photodiode has a simple structure in which an active layer is sandwiched between a transparent electrode and a metal electrode. In contrast to OLEDs, organic photodiodes (OPDs) utilize the organic semiconductor to absorb incident light and convert it to electric current. The structure and working principle are more like organic solar cells. Among the various organic photodetectors, organic photodiodes (OPDs) have been the most widely studied due to their fast response, high sensitivity, and full use of the existing research base of organic photovoltaics (OPVs).
Dye-Sensitized Solar Cells (DSSCs)
Dye-Sensitized Solar Cells (DSSCs) use photosensitizers adsorbed on the surface of nanocrystalline mesoporous titanium dioxide (TiO2) films, as well as electrolytes or solid charge-transporting materials, to convert light into electricity. They have many functions, including transparency, multicolor, and low-cost fabrication, and are deployed in glass facades, skylights, and greenhouses. Sensitizers are the key to DSSCs, which drive the operation of the entire cell by continuously absorbing light to generate a flow of electrons. Each sensitizer has its corresponding absorption spectrum distribution. To improve the matching of the absorption spectrum of the sensitizer with the solar spectrum, co-sensitization of multiple sensitizers is sometimes required to improve the conversion efficiency of solar cells.

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