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Potassium sulfite

Name: Potassium sulfite
Brand: ALDRICH

90%

Synonym(s):

dipotassiumsulfite

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About This Item

Linear Formula:

K₂SO₃

CAS Number:

10117-38-1

Molecular Weight:

158.26

EC Number:

233-321-1

MDL number:

MFCD00011387

UNSPSC Code:

12352302

PubChem Substance ID:

24884361

NACRES:

NA.22

Quality Level

200

Assay

90%

SMILES string

[K+].[K+].[O-]S([O-])=O

InChI

1S/2K.H2O3S/c;;1-4(2)3/h;;(H2,1,2,3)/q2*+1;/p-2

InChI key

BHZRJJOHZFYXTO-UHFFFAOYSA-L

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Related Categories

Salts

Application

Potassium sulfite (K₂SO₃) can be used as a catalyst in the oxidation of sulfur dioxide. It is also used as an anionic catalyst for the cyclotrimerization of aryl isocyanates to prepare heterocyclic symmetrical isocyanurates.

WGK

WGK 1

Flash Point(F)

Not applicable

Flash Point(C)

Not applicable

Certificates of Analysis (COA)

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Allylic selenosulfide rearrangement: a method for chemical ligation to cysteine and other thiols.

David Crich et al.

Journal of the American Chemical Society, 128(8), 2544-2545 (2006-02-24)

Alkylation of potassium selenosulfate with allylic halides gives Se-allyl seleno Bunte salts. On reaction with thiols at room temperature, these afford mixed dialkyl selenosulfides, which undergo 2,3-sigmatropic rearrangement with loss of selenium, either spontaneously or with assistance by triphenylphosphine, thereby

Sulfate catalysed multicomponent cyclisation reaction of aryl isocyanates under green conditions

Dekamin, Mohammad G, et al.

J. Chem. Res. (M), 2005(3), 177-179 (2005)

The reactivity of products of thermal interaction between ammonium meta-vanadate and potassium sulfite as catalysts for oxidation of sulfur dioxide

Fouda MFR, et al.

Applied Catalysis A: General, 223(1-2), 11-27 (2002)

Efficient photoelectrochemical hydrogen production from bismuth vanadate-decorated tungsten trioxide helix nanostructures.

Xinjian Shi et al.

Nature communications, 5, 4775-4775 (2014-09-03)

Tungsten trioxide/bismuth vanadate heterojunction is one of the best pairs for solar water splitting, but its photocurrent densities are insufficient. Here we investigate the advantages of using helical nanostructures in photoelectrochemical solar water splitting. A helical tungsten trioxide array is

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