Transition‐Metal‐Free C−S, C−Se, and C−Te Bond Formation from Organoboron Compounds

Sacramento, Manoela; Costa, Gabriel P.; Barcellos, Angelita M.; Perin, Gelson; Lenardão, Eder J.; Alves, Diego

doi:10.1002/tcr.202100021

Cited by 13 publications

(7 citation statements)

References 139 publications

(109 reference statements)

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“…Triselenium dicyanide (TSD) or dicyanogen triselenide (Se(SeCN) 2 ) represents an alternative direct source of ideal selenocyanating reagent for the synthesis of aromatic and heteroaromatic selenocyanates, which has been well known for a long time [39a–c] . In particular, for the direct C−H bond, selenocyanation reactions that involve in situ generation of dicyanogen triselenide utilizing selenium dioxide (SeO 2 ) and malononitrile (CH 2 (CN) 2 ) have gained popularity because they are more economical and pragmatic, and in recent years, significant evolution has been ended in the synthesis of various types of selenocyanated molecules [39d–g] . Very recently, Maddani and coworkers established the first selenocyanation of ketene dithioacetals ( 102 / 102’ ) with SeO 2 and CH 2 (CN) 2 in situ generated triselenium dicyanide under transition metal free conditions [40] .…”

Section: Synthetic Approaches Of Organo‐selenocyanates (Oscs)mentioning

confidence: 99%

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Organic Selenocyanates: Rapid Advancements and Applicationsin the Field of Organic Chemistry

Karmaker

Huo

2022

Asian J Org Chem

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The incorporation of the cyanato‐chalcogen group (OCN, SCN, and SeCN) has piqued the interest of many researchers in the field of modern organic synthetic chemistry. Methodologies for selenocyanation are far less advanced than those for OCN and SCN chemistry due to the scarcity of SeCN transfer reagents and synthetic approaches. It has also been discovered that the selenocyanate precursor (SeCN) performs significantly better than the thiocyanate (SCN) precursor in terms of pharmacological properties of organic scaffolds. Recent years, new reagents (nucleophilic, electrophilic, radical) and techniques were introduced that allowed the creation of the selenocyanato group uncomplicatedly under gentle reaction conditions, particularly in transition metal catalysis and photo‐/electro‐chemically influenced reactions, which were seemingly unimaginable. In this review, we have categorized a variety of techniques using various types of selenocyanate regents and their applications in the last decades, focusing on multiple catalysts for the preparation of organic selenocyanates and their derivatives.

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Section: Synthetic Approaches Of Organo‐selenocyanates (Oscs)mentioning

confidence: 99%

“…Organo‐selenocyanates (OSCs) have specifically been used to construct a number of organo‐selenium containing compounds. For a variety of purposes, selenocyanate‐containing organic compounds have gained considerable interest [39g,49] …”

Section: Synthetic Applications Of Selenocyanatesmentioning

confidence: 99%

Organic Selenocyanates: Rapid Advancements and Applicationsin the Field of Organic Chemistry

Karmaker

Huo

2022

Asian J Org Chem

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“…Of course, it should be mentioned that noncatalytic methods were successfully used for a long time for the preparation of organosulfur and other organochalcogen compounds and still are involved in organic synthesis. Just a few representative examples may be mentioned in this regard. ,,,,− We do not consider noncatalytic reactions in this review since we focus only on newly developed catalytic methodologies, which demonstrate a number of advantages and future potential.…”

Section: Introductionmentioning

confidence: 99%

Transition-Metal-Catalyzed C–S, C–Se, and C–Te Bond Formations via Cross-Coupling and Atom-Economic Addition Reactions. Achievements and Challenges

2022

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In the present review, we discuss recent progress in the field of C–Z bond formation reactions (Z = S, Se, Te) catalyzed by transition metals. Two complementary methodologies are consideredcatalytic cross-coupling reactions and catalytic addition reactions. The development of advanced catalytic systems is aimed at improved catalyst efficiency, reduced catalyst loading, better cost efficiency, environmental concerns, and higher selectivity and yields. The important rise of research efforts in sustainability and green chemistry areas is critically assessed. The paramount role of mechanistic studies in the development of a new generation of catalytic systems is addressed, and the key achievements, problems, and challenges are summarized for this field.

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“…14 A considerable number of methods to insert a phenylseleno group into (hetero)arenes or alkenes have been developed. [15][16][17][18][19] One of the most classic and common strategies is using various transition metals such as Pd, 20,21 Rh, [22][23][24][25] Cu, [26][27][28] Ni 29,30 etc. as catalysts (Scheme 1a).…”

Section: Introductionmentioning

confidence: 99%

Regioselective C–H chalcogenylation and halogenation of arenes and alkenes under metal-free conditions

et al. 2023

Org. Biomol. Chem.

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Transition‐Metal‐Free C−S, C−Se, and C−Te Bond Formation from Organoboron Compounds

Cited by 13 publications

References 139 publications

Organic Selenocyanates: Rapid Advancements and Applicationsin the Field of Organic Chemistry

Organic Selenocyanates: Rapid Advancements and Applicationsin the Field of Organic Chemistry

Transition-Metal-Catalyzed C–S, C–Se, and C–Te Bond Formations via Cross-Coupling and Atom-Economic Addition Reactions. Achievements and Challenges

Regioselective C–H chalcogenylation and halogenation of arenes and alkenes under metal-free conditions

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