Novel, very stable ruthenium and osmium containing terminal phosphinidene complexes [(eta(6)-Ar)(L)M=Mes*] (Ar=benzene, p-cymene; L=PR(3), CO, and RNC) have been prepared by dehydrohalogenation of novel [(eta(6)-Ar)MX(2)(PH(2)Mes*)] complexes in the presence of a stabilizing ligand. Xray crystal structures are reported for [(eta(6)-C(6)H(6))(PPh(3))Rud=PMes*] (9) and [(eta(6)-pCy)(PPh(3))Os=PMes*] (4). Dehydrohalogenation in the absence of a stabilizing ligand resulted in the new P-spiroannulated Ru(2)P(2)-ring structure 16. Dehydrohalogenation in the presence of but-2-yne gave a novel phosphaallyl complex [(eta(6)-Ar)Ru(eta(3)-R(2)PC(Me)CHMe)] 26, for which an X-ray crystal structure is reported. The mechanism by which 16 and 26 are obtained is presumed to involve the intermediate formation of the 16-electron (eta(6)-benzene)Rud=PMes* phosphinidene complex.
Stable, crystalline iridium-complexed phosphinidenes, Cp*(L)IrdPR, are readily synthesized by (a) the reaction of Cp*(L)IrCl 2 (2, L) PPh 3) with LiPHMes* and (b) dehydrohalogenation of Cp*(PH 2 R)IrCl 2 (5, R) Mes*, Is, Mes) with in situ capturing of transient Cp*Irt PR (4) with phosphines, phosphites, arsines, isocyanides, and carbon monoxide (L). Cp*Irt PR eluded direct detection. The X-ray crystal structures are reported for Cp*(PPh 3)IrdPMes* (3) and Cp*(CO)IrdPMes* (15). The more congested 3 has an E configuration for its IrdP bond, whereas 15 is obtained in its Z form. The 31 P NMR chemical shifts and 2 J PP coupling constants are diagnostic for the E and Z forms. More shielded phosphinidene resonances and larger coupling constants are typical for the E isomers. These iridium-complexed phosphinidenes react with gem-diiodides to form phosphaalkenes, but not with carbonyl groups.
Novel terminal rhodium-and cobalt-complexed phosphinidenes, Cp*(PR 3 ) and Cp(PPh 3 )CodPAr (8), were obtained by dehydrohalogenation of the primary phosphine complexes Cp*RhCl 2 (PH 2 Ar) (2) and CpCoI 2 (PH 2 Ar) (7) in the presence of a phosphine. X-ray crystal structures are reported for Cp*(PPh 3 )RhdPMes* (3) and Cp(PPh 3 )CodPMes* (8). A comparative reactivity study and a computational survey were performed on the Co-, Rh-, and Ir-containing phosphinidene complexes. All react with organic dihalides to form phosphaalkenes, with the rhodium congener being far more reactive than the iridium and cobalt complexes. Density functional theory calculations give geometrical parameters and 31 P NMR chemical shifts in good agreement with experimental data. The rhodium congeners exhibit the most pronounced charge separation of the RhdP bond, which may explain its higher reactivity. The M-L bond is strong in all Cp(L)MdPH (M ) Co, Rh, Ir) complexes and inhibits reactivity at the metal center. Comparisons with the Zr-containing complex Cp 2 (PH 3 )Zr-PH are made.
Bidentate ligands of the type Mes*PC(R)Py
((E)-
2, R = H; (Z)-
9, R
= SiMe3; Mes* =
supermesityl = 2,4,6-tri-tert-butylphenyl; Py =
2-pyridyl) were synthesized. Ligand
(E)-
2
was synthesized by reacting
Mes*P(Li)SiMe2(t-Bu)
(4) with 2-pyridinecarboxaldehyde.
Ligand (Z)-
9 was synthesized via a
PdCl2(dppb)-catalyzed coupling reaction
between
2-bromopyridine and Mes*PC(SiMe3)M
((E)-
7, M = ZnCl; (Z)-
8,
M = MgBr). Compound
(E)-
2 was also characterized by an X-ray crystal
structure determination; it has a planar
structure with the (E)-configuration. The complexes
η1,η1-[Mes*PC(R)Py]PdCl2
(11, R =
H; 12, R = SiMe3) were prepared by the
reaction of bis(benzonitrile)palladium
dichloride
with (E)-
2 and (Z)-
9,
respectively. The complexes
η1,η1-[Mes*PC(R)Py]MePdCl
(13, R =
H; 14, R = SiMe3) were obtained by a ligand
exchange reaction of MePdCl(COD) with
(E)-
2
and (Z)-
9, respectively. Complex
13 was alternatively prepared by reaction of 11
with
methylmagnesium chloride. Complex 14 was unambiguously
identified by an X-ray crystal
structure determination. Both 13 and 14
reacted with CO, resulting in the acetyl complexes
η1,η1-[Mes*PC(R)Py]AcPdCl (16, R =
H; 17, R = SiMe3).
Novel functionalized phosphaalkene-based bidentate ligands of the type 1-[(E)-Mes*PC(H)]-3-R-benzene (8, R = N-phenylcarbaldimino; 2, R = 2-pyridyl; Mes* = 2,4,6-tri-tert-butylphenyl) were prepared via a Pd(0)-catalyzed cross-coupling reaction of (Z)-bromophosphaalkene (Z)-
1 with Grignard reagents. The reaction of 8 and 2 with MePdCl(COD)
furnished three-membered phosphapalladacycles of the type
(9, R = N-phenylcarbaldimino; 10, R = 2-pyridyl), displaying intramolecular coordination
between the phosphine ligand and palladium(II). The structure of 10 was established by an
X-ray structure determination, showing a dimeric structure. The addition of triphenylphosphine to 9 and 10 causes rupture of the interconnecting Pd−N bonds, furnishing 11 and 12,
respectively.
Several novel phosphaalkenes (E)-Mes*P=CHC 6 H 4 X (6; X = Me 3 Si, Me 3 Sn, CHO, COOH, CN) were prepared and, together with other known members of this series, subjected to an analysis of linear free-energy relationships based on the values of pK a and values of δ( 13 C para ) of substituted benzoic acids and on the values of δ( 13 C para ) of substituted bromobenzenes. These analyses indicate that the (E)-Mes*P=CH group is a weak electron donor with a predominantly inductive effect (σ p = −0.1) on a neighboring benzene ring; resonance interactions are of minor importance. This
The properties of the 16‐electron phosphinidene complex [CpRIrPR] were investigated experimentally and theoretically. Density functional theory calculations show a preferred bent geometry for the model complex [CpIrPH], in contrast to the linear structure of [CpIrNH]. Dimerization to give [{CpIrPH}2] and ligand addition to afford [Cp(L)IrPH] (L=PH3, CO) were calculated to give compounds that were energetically highly favorable, but which differed from the related imido complexes. Transient 16‐electron phosphinidene complex [Cp*IrPAr] could not be detected experimentally. Dehydrohalogenation of [Cp*IrCl2(PH2Ar)] in CH2Cl2 at low temperatures resulted in the novel fused‐ring systems 17 (Ar=Mes*) and 20 (Ar=Mes), with dimeric [{Cp*IrPAr}2] being the likely intermediate. Intramolecular CH bond activation induced by steric factors is considered to be the driving force for the irreversible formation of 17 and 20. ONIOM calculations suggest this arises because of the large steric congestion in [{Cp*IrPAr}2], which forces it toward a more reactive planar structure that is apt to rearrange.
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