Phosphorus Heterocycles

“…Generally, strong electron-withdrawing and/or sterically bulky ligands impart geometric constraints that in turn generate reactive 4SQ sites for use in main group catalysis. ,, However, the Lewis acidity of these hypervalent phosphorus centers arises from the preferred formation of two 3c–4e bonds with moderate strength in 4SQ over a single, strong 3c–4e bond in the corresponding 3BP geometry. While the 4SQ geometry is slightly energetically favored over 3BP, these compounds dynamically exchange between these two geometries in solution, not unlike the Berry pseudorotation mechanism invoked for other pentacoordinate main group species. ,, The 4SQ geometry is desirable in the solid state as this allows for a parallel arrangement between the extended conjugated scaffolds of adjacent molecules to enhance their intermolecular π–π interactions, which in turn mutually protect the neighboring phosphorus centers from exposure to nucleophiles (Figure , inset). It is noteworthy that this interaction persists not only in the solid state but also in solution at very low concentrations.…”

“…This allows installing a second exocyclic P substituent that, with its inherent P–E σ* orbital, can engage in a second σ*−π* interaction, thus further lowering the energy level of the LUMO (Figure ). − ,, …”

Unique Phosphorus-Based Avenues for the Tuning of Functional Materials

“…Generally, strong electron-withdrawing and/or sterically bulky ligands impart geometric constraints that in turn generate reactive 4SQ sites for use in main group catalysis. ,, However, the Lewis acidity of these hypervalent phosphorus centers arises from the preferred formation of two 3c–4e bonds with moderate strength in 4SQ over a single, strong 3c–4e bond in the corresponding 3BP geometry. While the 4SQ geometry is slightly energetically favored over 3BP, these compounds dynamically exchange between these two geometries in solution, not unlike the Berry pseudorotation mechanism invoked for other pentacoordinate main group species. ,, The 4SQ geometry is desirable in the solid state as this allows for a parallel arrangement between the extended conjugated scaffolds of adjacent molecules to enhance their intermolecular π–π interactions, which in turn mutually protect the neighboring phosphorus centers from exposure to nucleophiles (Figure , inset). It is noteworthy that this interaction persists not only in the solid state but also in solution at very low concentrations.…”

“…This allows installing a second exocyclic P substituent that, with its inherent P–E σ* orbital, can engage in a second σ*−π* interaction, thus further lowering the energy level of the LUMO (Figure ). − ,, …”

Unique Phosphorus-Based Avenues for the Tuning of Functional Materials

“…Phosphorus containing heterocycles can be subdivided by coordination number, with three coordinate and four coordinate geometries (σ 3 , σ 4 ) being the most commonly studied systems. 18–24 In particular, σ 3 ,λ 3 -phospholes have drawn much attention, as their (i) trigonal pyramidal geometry and reduced aromaticity allow for unusual means to tune electronic delocalization into the π-system, and (ii) the lone pair on phosphorus offers additional opportunities to modulate HOMO and LUMO levels. Specifically, chemical modification of the P atom by oxidation, alkylation, or coordination by Lewis acids and metals has led to tunable new π-conjugated systems with diverse photophysical properties.…”

Luminescent 1H-1,3-benzazaphospholes

“…Over the past few decades, the organophosphorus chemistry field has witnessed a growing research interest since organophosphorus compounds have found widespread applications in medicinal chemistry, organometallic chemistry, agricultural chemistry, and materials chemistry. 1 Specifically, phosphorodithioate compounds bearing the thiophosphoryl bond have useful properties such as insecticides (Fig. 1, A and B ) and neurotoxins (Fig.…”

Catalyst-free thiophosphorylation of in situ formed ortho-quinone methides