Synlett 2005(3): 541-542  
DOI: 10.1055/s-2004-862370
SPOTLIGHT
© Georg Thieme Verlag Stuttgart · New York

HOF·CH3CN Complex

Siddhartha Gogoi*
Natural Products Chemistry Division, Regional Research ­Laboratory (CSIR), Jorhat-785006, Assam, India
e-Mail: siddhukaku_7@yahoo.co.in;

Further Information

Publication History

Publication Date:
04 February 2005 (online)

Biographical Sketches

Siddhartha Gogoi was born in Sivasagar, Assam (India) in 1977. He completed his B.Sc. (1998) degree from Dibrugarh University and M.Sc. (2000) degree in chemistry from Gauhati University, ­Guwahati (India). He is currently working toward a Ph.D. in organic chemistry under the supervision of Dr. N. C. Barua at the Regional Research Laboratory in Jorhat, India. His research interests are the total synthesis of bioactive natural products and the development of new methodologies.

Introduction

HOF was originally synthesized by Appelman [1] in 1971, but was found to be a very unstable substance and of little use in synthetic chemistry as it was difficult to prepare and could be generated only in very minute amounts. A few years ago, Rozen developed a new way to prepare and stabilize it through complexation with acetonitrile. [2] Whereas neat HOF can be unpredictably explosive at temperatures above -40 ºC, its acetonitrile complex (HOF·CH3CN) is much more stable.

HOF·CH3CN complex is a potent oxygen-transfer reagent for a variety of reactions, some of which are occasionally difficult on certain substrates. It reacts very efficiently with a large variety of organic compounds, resulting in either an oxidation or a transfer of an oxygen atom from the reagent to the substrate. This reagent can be applied to the synthesis of epoxides from various olefins, ketones from methyl ethers, esters by the Baeyer-Villiger reaction, ­sulfones from sulfides, nitro compounds from amines and amino acids, N-oxides from tertiary amines, and other conversions. More recently, HOF·CH3CN complex has been used in the direct oxidation of aliphatic and selected aromatic azides to nitro compounds, both very efficiently and in excellent yields.

Its uniqueness is based on its oxygen, which becomes a strongly electrophilic species because of it being bonded to highly electronegative fluorine. Its reactions have been shown to be ionic in nature and are usually complete in a few minutes at temperatures ranging from 0 ºC to 25 ºC.

Preparation:

HOF·CH3CN complex is simply prepared in a glass reactor by ­bubbling nitrogen-diluted fluorine (10-15%) into aqueous acetonitrile (10% H2O in CH3CN) at 0 ºC. The product is stable at 0 ºC for a few hours.2

Scheme 1 Preparation of HOF·CH3CN complex

Abstracts

(A) Rozen and coworkers reported the first direct oxidation of ­aliphatic and aromatic azides into nitro compounds with HOF·CH3CN complex in excellent yields. [3]

(B) As a strong oxidant, HOF·CH3CN complex can oxidize aromatic amines to nitroarenes in high yields. [4] It can also oxidize the amino group of a-amino esters to a-nitro esters without affecting the aromatic ring. [5]

(C) HOF·CH3CN complex is an ecologically friendly oxidizing agent and can oxidize alcohols [6] and methyl ethers to ketones. ­Ketones also undergo Baeyer-Villiger oxidation to give esters ­under the same reaction conditions. [7] All these reactions are ionic in nature.

(D) With its strong electrophilic oxygen, HOF·CH3CN complex is an excellent oxygen transfer agent [8] that epoxidizes a wide variety of alkenes and alkynes, including very deactivated ones that cannot be directly epoxidized by other methods.

(E) HOF·CH3CN complex can oxidize all types of sulfides to ­sulfones in excellent yields in only a few minutes at or below room temperature. [9] The reaction proceeds through the formation of ­sulfoxides which, at low temperatures of around -78 °C, can be isolated in good yields.

(F) HOF·CH3CN complex can also hydroxylate [10] and otherwise oxidize many aromatic compounds, though yields are moderate.

Scheme 1 Preparation of HOF·CH3CN complex