Dynamic Cross-Exchange in Halophosphonium Species: Direct Observation of Stereochemical Inversion in the Course of an S 2 Process.

The complex fluxional interconversions between otherwise very similar phosphonium bromides and chlorides R PX X (R=Alk, Ar, X=Cl or Br) were studied by NMR techniques. Their energy barriers are typically ca. 11 kcal mol , but rise rapidly as bulky groups are attached to phosphorus, revealing the importance of steric factors.

Two Independent Orthogonal Stereomutations at a Single Asymmetric Center: A Narcissistic Couple.

The energy barriers in our recently discovered Walden-type inversion of chlorophosphonium salts are similar to those for Cope rearrangements of caged cyclic hydrocarbons. Therefore, we have designed a molecular system that integrates the two processes, thereby producing the first embodiment of a chemical species that can undergo two entirely different and independent stereomutation mechanisms at the same nominal asymmetric center. Thus, the energy barrier to the rearrangement of 9-phenyl-9-phosphabarbaralane oxide, which is easily prepared by a new high-yielding synthesis, was found to be roughly 11 kcal mol .

Degenerate nucleophilic substitution in phosphonium salts.

Rates and energy barriers of degenerate halide substitution on tetracoordinate halophosphonium cations have been measured by NMR techniques (VT and EXSY) using a novel experimental design whereby a chiral substituent ((s)Bu) lifts the degeneracy of the resultant salts. Concomitantly, a viable computational approach to the system was developed to gain mechanistic insights into the structure and relative stabilities of the species involved. Both approaches strongly suggest a two-step mechanism of formation of a pentacoordinate dihalophosphorane via backside attack followed by dissociation, resulting in inversion of configuration at phosphorus.

Cleavage of P=O in the presence of P-N: aminophosphine oxide reduction with in situ boronation of the P(III) product.

In contrast to tertiary phosphine oxides, the deoxygenation of aminophosphine oxides is effectively impossible due to the need to break the immensely strong and inert PO bond in the presence of a relatively weak and more reactive PN bond. This long-standing problem in organophosphorus synthesis is solved by use of oxalyl chloride, which chemoselectively cleaves the PO bond forming a chlorophosphonium salt, leaving the PN bond(s) intact. Subsequent reduction of the chlorophosphonium salt with sodium borohydride forms the P(III) aminophosphine borane adduct.