Elemental Sulfur: A Simple, Economic, and Versatile Reagent

Biographical Sketches

Introduction

Elemental sulfur is a paled yellow, odorless and brittle solid, which is insoluble in water, but soluble in CS₂. [¹] It is very inexpensive and easy available, because of its abundance in many naturals’ sources (petroleum crude, minerals, etc.). [²] Elemental sulfur appears in several allotropic forms: octahedral, rhombic or α-sulfur, monoclinic, prismatic or β-sulfur. [¹] Both the rhombic and monoclinic forms are made up of eight sulfur atoms arranged in a puckered structure. Literature reveals that S₈ has been extensively used in numerous organic transformations, including synthesis of mercaptopurines, [³] oxazolidinones, [4] aminothiophenes, [5] reduction of nitroarenes, [6] and as oxidation agents. [7] These and some other applications are described below.

Abstracts

(A) A one-pot conversion of 4,5-diamino-6-chloropyrimidines into 6-mercaptopurines was presented by Tandel et al. [³] The reaction is easy to perform by simply heating of a mixture of pyrimidine, aldehydes and an equimolar amount of elemental sulfur in DMF. All ­reactions were carried out in 17 hours with good to high yields (18-93%) and the method uses an in situ generated H2S for the conversion of the chloro into the mercapto group.
(B) McLaughlin and Barnes reported an efficient method for the transformation of functionalized nitroarenes to the corresponding anilines with elemental sulfur and base in good yields. [6] The process takes advantage of the capacity of sulfur to be an inexpensive 2-electron reductant. The reaction conditions are also notable for their compatibility with a range of functional groups and use of a mild base.
(C) Recent efforts have been directed to study the use of germanium(II) hydrides in hydrogenation reactions. [8] The rapid simultaneous insertion of elemental sulfur into the germylene hydrogen bond and oxidative addition of sulfur to the germylene atom has been reported. The product is the first representative example of a dithiocarboxylic acid analogue with a heavier group 14 element and a terminal S-H bond, and constitute a new precursor for many metal complexes.
(D) Elemental sulfur has proved to be an efficient component in the one-pot synthesis of 2,3-dihydropyrimidinthiones via multicomponent coupling with terminal alkynes and carbodiimides. [9]
(E) The solvent-free reaction between elemental sulfur and limonene in the presence of γ-terpinene afforded the isothiocineole in 36% yield, useful in the asymmetric epoxidation and aziridination reactions. Moreover, the sulfide product was used in the synthesis of the cinchona alkaloids, quinine and quinidine, interesting molecules with a relevant history in medicine, synthesis, and catalysis. [¹0]
(F) Elemental sulfur catalyzed the oxidative condensation-cyclization of aromatic aldehydes and aryl-2-pyridilmethyl amines afforded an elegant access to appropriate 1,3-diarylated imidazo[1,5-a]pyridines. The products show a wide variety of fluorescent emissions at 454-524 nm. [7]
(G) The reaction of tri(1-propenyl)-amine with elemental sulfur can be realized to the synthesis of thiazoles in good yield. [¹¹]
(H) An interesting strategy to mono-sulfuration of alkenes has been reported by Sugihara and co-workers. [¹²] The reaction of syn-bibenzonorbornenylidene with elemental sulfur furnished the episulfide exclusively in 83% yield with retention of the original stereochemistry.
(I) A series of 2-oxazolidinones were synthesized by thiocarboxylation of 2-amonoethanols with carbon monoxide using elemental sulfur, followed by the oxidative cyclization by molecular oxygen. [4]
(J) The most convergent and well-established classical approach for the synthesis of 2-aminothiophenes is Gewalds’ protocol, which involves the multicomponent reaction of a ketone with an activated nitrile and elemental sulfur in the presence of an organic base. [5] Recently, Zhang et al. reported that the PEG-bound cyanoacetic ester also undergoes the Gewald reaction under microwave irradiation.

References

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References

• 1 The Merck Index  14^th ed; O’Neil MJ. Heckelman PE. Koch CB. Roman KJ. Kenny CM. D’Arecca MR. Eds.; Merck; New York: 2006. 
  Google Scholar
• 2 Borah D. Energy Fuels  2004,  18:  1463 
  CrossrefGoogle Scholar
• 3 Tandel S. Bliznets I. Ebinger K. Ma Y.-A. Bhumralkar D. Thiruvazhi M. Tetrahedron Lett.  2004,  45:  2321 
  CrossrefGoogle Scholar
• 4 Mizuno T. Takahashi J. Ogawa A. Tetrahedron  2002,  58:  7805 
  CrossrefGoogle Scholar
• 5 Zhang H. Yang G. Chen J. Chen Z. Synthesis  2004,  3055 
  Artikel in Thieme ConnectGoogle Scholar
• 6 McLaughlin MA. Barnes DM. Tetrahedron Lett.  2006,  47:  9095 
  CrossrefGoogle Scholar
• 7 Shibahara F. Sugiura R. Yamaguchi E. Kitagawa A. Murai T. J. Org. Chem.  2009,  74:  3566 
  CrossrefGoogle Scholar
• 8 Jana A. Ghoshal D. Roesky HW. Objartel I. Schwab G. Stalke D. J. Am. Chem. Soc.  2009,  131:  1288 
  CrossrefGoogle Scholar
• 9 Wang Z. Wang Y. Zhang W.-X. Hou Z. Xi Z. J. Am. Chem. Soc.  2009,  131:  15108 
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• 10 Illa O. Arshad M. Ros A. McGarrigle EM. Aggarwal VK. J. Am. Chem. Soc.  2010,  132:  1828 
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• 11 Musorin GK. Russ. J. Org. Chem.  2002,  38:  591 
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• 12 Sugihara Y. Noda K. Nakayama J. Tetrahedron Lett.  2000,  41:  8913 
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