Understanding Reactive Sulfur Species through P/S Synergy

We investigated the differential oxidative and nucleophilic chemistry of reactive sulfur and oxygen anions (SSNO–, SNO–, NO2 –, S4 2–, and HS–) using the simple reducing electrophile PPh2Cl. In the case of SSNO– reacting with PPh2Cl, a complex mixture of mono and diphosphorus products is formed excl...

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Veröffentlicht in:	Inorganic chemistry 2023-09, Vol.62 (35), p.14339-14343
Hauptverfasser:	Wade Wolfe, Michael M., Pluth, Michael D.
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container_title	Inorganic chemistry
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creator	Wade Wolfe, Michael M. Pluth, Michael D.
description	We investigated the differential oxidative and nucleophilic chemistry of reactive sulfur and oxygen anions (SSNO–, SNO–, NO2 –, S4 2–, and HS–) using the simple reducing electrophile PPh2Cl. In the case of SSNO– reacting with PPh2Cl, a complex mixture of mono and diphosphorus products is formed exclusively in the P(V) oxidation state. We found that the phosphine stoichiometry dictates selectivity for oxidation to P=S/P=O products or transformation to P2 species. Interestingly, only chalcogen atoms are incorporated into the phosphorus products and, instead, nitrogen is released in the form of NO gas. Finally, we demonstrate that more reducing anions (S4 2– and HS–) also react with PPh2Cl with P=S bond formation as a key reaction driving force.
doi_str_mv	10.1021/acs.inorgchem.3c01976
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title	Understanding Reactive Sulfur Species through P/S Synergy
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