11113-56-7

Basic information

• Product Name: Chromium fluoride
• Synonyms: Chromium(III) fluoride, anhydrous; chromium trifluoride; Chromic Fluoride; Chromiumfluorideanhydrousgreenpowder; Chromiumfluoride; chromium(3+) trifluoride; difluoro(dioxo)chromium; chromous trifluoride; Chromium fluoride
• CAS NO: 11113-56-7
• Molecular Weight: 0
• EINECS: 232-137-9
• Mol File: 11113-56-7.mol
• Article Data: 6

Chemical Properties

• Melting Point: 1000℃
• Appearance: /
• CAS DataBase Reference: Chromium fluoride(CAS DataBase Reference)
• NIST Chemistry Reference: Chromium fluoride(11113-56-7)
• EPA Substance Registry System: Chromium fluoride(11113-56-7)

Safety Data

• Hazardous Substances Data: 11113-56-7(Hazardous Substances Data)

Usage

Description

Chromium fluoride, with the chemical formula CrF3, is a green solid that is insoluble in water. It is a chemical compound known for its use in various applications due to its unique properties, including its role as a catalyst in organic synthesis and as a reagent in organic chemistry. Additionally, it serves as a source of chromium in certain chemical processes and has been investigated for its potential in photonic applications owing to its optical characteristics. However, it is essential to handle chromium fluoride with care due to its toxic nature and potential to cause irritation to the skin, eyes, and respiratory system.

Uses

Used in Organic Synthesis:
Chromium fluoride is used as a catalyst in organic synthesis for facilitating various chemical reactions. Its catalytic properties enable the efficient conversion of reactants to products, making it a valuable component in the synthesis of complex organic molecules.
Used in Organic Chemistry:
In the field of organic chemistry, chromium fluoride is employed as a reagent. It aids in the execution of specific chemical transformations, contributing to the advancement of organic reactions and the study of organic compounds.
Used as a Source of Chromium:
Chromium fluoride can be utilized as a source of chromium in some chemical processes. Its ability to provide chromium makes it useful in applications where chromium is required, such as in the production of certain alloys or chemical compounds.
Used in Photonic Applications:
Due to its optical properties, chromium fluoride has been studied for its potential use in photonic applications. Its unique characteristics make it a candidate for use in the development of photonic devices and systems, which could have implications in various industries, including telecommunications and computing.

InChI:InChI=1/Cr.3FH/h;3*1H/q+2;;;/p-3

Upstream product

• 7440-47-3 chromium 
• 7782-41-4 fluorine 
• 2551-62-4 sulfur(VI) hexafluoride 
• 75-73-0 carbon tetrafluoride 
• 7788-97-8 chromium(III) fluoride 

Relevant articles and documents

The rotational spectrum of the CrF radical in the X6∑+ state

The rotational spectrum of the CrF radical in the X6∑+ state was observed by employing a source modulation microwave spectrometer. The CrF radical was generated in a free space cell by a dc glow discharge in CF4 and He. The chromium atom was supplied by the sputtering reaction from chromium powder placed over a lower surface of the cylindrical electrodes. The transitions with N=12-11 to 20-19 were measured in the region between 270 and 460 GHz. The rotational, centrifugal distortion and several fine-structure constants were obtained by a least squares analysis.

Electronic properties of CrF and CrCI in the X6∑+ state: Observation of the halogen hyperfine structure by Fourier transform microwave spectroscopy

The rotational spectra of the CrF and CrCl radicals in the X 6σ+ was discussed. It was stated that the CrF and CrCl radicals were generated by the reaction of laser-ablated Cr with F 2 and Cl2, respectively dilu

Fluorination of complexed chromium atoms and molecules

Three new electronic states of CrF and two electronic transitions tentatively assigned to a polyatomic 'CrxF' (Cr2F) emitter are observed in the chemiluminescent flame resulting from the reaction between entrained (He,CO) chromium vapor and molecular fluorine under multiple collision conditions. The CrF transitions are vibrationally analyzed and term symbols assigned. Each of the new transitions correlations well with a previously observed transition in the 'pseudo-isoelectronic' molecules MnO, CrH, or CrCl. This correlation provides a basis for determining the electronic configuration of the CrF states and a guideline for predicting unobserved electronic transitions in the 'pseudo-isoelectronic' molecules.