13455-00-0

Basic information

• Product Name: DIPHOSPHORUS TETRAIODIDE
• Synonyms: hypodiphosphoroustetraiodide;DIPHOSPHORUS TETRAIODIDE;AURORA KA-1083;PHOSPHORUS DIIODIDE;diphosphorous tetraiodide;Hypodiiphosphorus tetraiodide;Tetraiododiphosphine;Diphosphorus tetraiodide,95%
• CAS NO: 13455-00-0
• Molecular Formula: I₄P₂
• Molecular Weight: 569.57
• EINECS: 236-646-7
• Product Categories: Electronic Chemicals;Micro/Nanoelectronics;Others
• Mol File: 13455-00-0.mol
• Article Data: 4

Chemical Properties

• Melting Point: 124-127 °C(lit.)
• Appearance: orange to red powder
• Storage Temp.: 2-8°C
• CAS DataBase Reference: DIPHOSPHORUS TETRAIODIDE(CAS DataBase Reference)
• NIST Chemistry Reference: DIPHOSPHORUS TETRAIODIDE(13455-00-0)
• EPA Substance Registry System: DIPHOSPHORUS TETRAIODIDE(13455-00-0)

Safety Data

• Hazard Codes: C
• Statements: 34-37
• Safety Statements: 26-36/37/39-45
• RIDADR: UN 3260 8/PG 2
• WGK Germany: 3
• F: 1-8-10
• HazardClass: 4.1
• PackingGroup: II
• Hazardous Substances Data: 13455-00-0(Hazardous Substances Data)

Usage

Description

Diphosphorus tetraiodide, also known as phosphorus iodide, is an orange crystalline solid with the chemical formula P2I4. It is a reagent used in organic synthesis and exhibits a high affinity for oxygen. Its unique chemical properties allow it to be used in various substitution and conversion reactions in the field of chemistry.

Uses

Used in Organic Synthesis:
Diphosphorus tetraiodide is used as a reagent in organic synthesis for various chemical reactions. Its high affinity for oxygen makes it a valuable compound in the synthesis of complex organic molecules.
Used in Substitution of Alcohol:
Diphosphorus tetraiodide is used as a substitute for alcohol to form alkyl iodides. This application is particularly useful in the synthesis of organic compounds that require the presence of an alkyl iodide group.
Used in Conversion of Carboxylic Acids to Nitriles:
Diphosphorus tetraiodide is also used in the conversion of carboxylic acids to nitriles. This conversion is essential in the synthesis of various organic compounds, including pharmaceuticals and agrochemicals, where nitriles are a common functional group.
Used in Chemical Research:
As a chemical with unique properties, diphosphorus tetraiodide is used in research laboratories to study its reactivity and potential applications in various chemical reactions and processes.

InChI:InChI=1/I4P2/c1-5(2)6(3)4

Upstream product

• 7553-56-2 iodine 
• 7719-12-2 phosphorus trichloride 
• 7803-51-2 phosphan 
• 164596-64-9 phosphonium iodide 
• 13455-01-1 phosphorous triiodide 
• 7803-52-3 stibane 
• 12185-10-3 phosphorous 
• 807613-82-7 Ag[Al(OtBuF)4]*dichloromethane 
• 345901-94-2 [Ag(η2-P4)2][Al(OC(CF3)3)4] 
• 12185-10-3 phosphorus 
• 7790-99-0 Iodine monochloride 
• 7790-48-9 tellurium(IV) iodide 
• 10034-85-2 hydrogen iodide 
• 12185-09-0 diphosphane 

Downstream Products

• 478620-64-3 5-(3,5-Dichloro-phenylsulfanyl)-1-isopropyl-4-pyridin-4-ylmethyl-1H-pyrazole-3-carboxylic acid ethyl ester 
• 7553-56-2 iodine 
• 13598-36-2 phosphonic Acid 
• 700796-61-8 tetrahydroxydiboron 
• 7803-51-2 phosphan 
• 86119-84-8 phosphoric acid 
• 10034-85-2 hydrogen iodide 
• 13455-01-1 phosphorous triiodide 
• 7803-60-3 hypophosphoric acid 
• 20267-10-1 subdiphosporous acid 
• 12019-11-3 copper phosphide 
• 13767-71-0 copper(II) iodide 
• 12185-10-3 phosphorous 
• 7790-48-9 tellurium(IV) iodide 

Relevant articles and documents

Substitution of conventional high-temperature syntheses of inorganic compounds by near-room-temperature syntheses in ionic liquids

The high-temperature syntheses of the low-valent halogenides P2I4, Te2Br, a-Te4I4, Te4(Al2Cl7)2, Te4(Bi6Cl20), Te8(Bi4Cl14), Bi8(AlCl4)2, Bi6Cl7, and Bi6Br7, as well as of WSCl4 andWOCl4 have been replaced by resource-efficient low-temperature syntheses in room temperature ionic liquids (RTILs). The simple one-pot syntheses generally do not require elaborate equipment such as twozone furnaces or evacuated silica ampoules. Compared to the published conventional approaches, reduction of reaction time (up to 80%) and temperature (up to 500 K) and, simultaneously, an increase in yield were achieved. In the majority of cases, the solid products were phase-pure. X-Ray diffraction on single crystals (redetermination of 11 crystal structures) has demonstrated that the quality of the crystals from RTILs is comparable to that of products obtained by chemical transport reactions.

Preparation and spectroscopic characterization of difluorophosphorane, PH3F2. 31P NMR spectrum of protonated diphosphine, P2H5+

The preparation of difluorophosphorane, PH3F2, from the reaction of diphosphine and hydrogen fluoride is reinvestigated; it has been characterized by multinuclear (1H, 19F, 31P) NMR spectroscopy. Complete infrared and Raman low-temperature spectra of difluorophosphorane are reported. It reacts with alkali-metal fluorides to give phosphine and hexafluorophosphates(V). On the basis of 31P NMR spectroscopic results, a reaction mechanism for the formation of PH3F2 is proposed. The byproducts of the reaction were PH2F3, (PH)n, and P2H5+; the last was observed for the first time. In carbon disulfide solution, diphosphine neither reacts with hydrogen halides to yield protonated diphosphine nor interacts with hydrogen fluoride to form difluorophosphorane.