Nucleophilic Phosphinidene Complexes: Access and Applicability

Aktaş, Halil; Slootweg, J. Chris; Lammertsma, Koop

doi:10.1002/anie.200905689

Cited by 212 publications

(145 citation statements)

References 127 publications

(107 reference statements)

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“…The chemistry of these two classes of molecules is now being intensively explored. 4,21,22,[27][28][29] (ii) The presence and nature of metal-main group element multiple bonding (MdP, MtP) in these complexes is of theoretical and reactivity interest. 30 (iii) In terminal M-PR molecules, the phosphorus atom is in a low oxidation state (þ1) and coordination number (2), providing an opportunity to explore fundamentally different chemistry at a P(I) center.…”

Section: ' Introductionmentioning

confidence: 99%

“…(iv) Like metal-carbene complexes, phosphinidene analogues have considerable potential in phosphaorganic synthesis and catalytic chemistry. 4 Our own interest in terminal phosphinidene complexes was stimulated by a longstanding interest in chemical transformations at bridging, μ-PR ligands in clusters 32,33 and by the discovery in 2001 of a synthetic route to isolable, cationic, terminal phosphinidene complexes of molybdenum and tungsten, [Cp*M(CO) 3 34 At the time these were the first fully characterized, electrophilic, terminal phosphinidene complexes, although NMR spectroscopic evidence had been reported 35 for a related iron cation, [Cp*Fe(CO) 2 …”

Section: ' Introductionmentioning

confidence: 99%

“…þ , and the phosphaorganic chemistry of transient electrophilic phosphinidenes such as [(CO) 5 WdPR] and [(CO) 4 FedPR)],generatedinsitu,hadbeen e l e g a n t l ye x p l o r e db yM a t h e y 36 and co-workers and Lammertsma et al 37 The Lammertsma group has recently reported the direct observation of the phosphinidene complex [W(CO) 5 (η 1 -PAr)] (Ar = aryl) by electrospray ionization tandem mass spectrometry (ESI-MS/MS), and the chemistry displayed by this reactive species matches that observed in solution. 38 Over the past few years we have isolated a series of cationic, terminal complexes including the remaining member [Cp*Cr(CO) 3 -{PN 21,[23][24][25]34 These molecules, all of which have been structurally characterized, display several important features.…”

Section: ' Introductionmentioning

confidence: 99%

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Synthesis and Structural Characterization of the First Thermally Stable, Neutral, and Electrophilic Phosphinidene Complexes of Vanadium

et al. 2011

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The first thermally stable, neutral, electrophilic phosphinidene complexes of vanadium, [CpV(CO)3{η1-P(NR2)}] (R = i Pr (3a), Cy (3b)), have been prepared by the reaction of [Na]2[CpV(CO)3] with Cl2PNR2. The molecules 3a and 3b have been characterized by microanalysis, IR, and 1H and 31P{1H} NMR spectroscopy, and for 3a also by single-crystal X-ray diffraction. The structure of 3a exhibits a piano stool geometry closely related to that of CpV(CO)4 with an η1-phosphinidene ligand replacing CO in one of the basal coordination sites of the vanadium atom (V(1)−P(1) = 2.300(2) Å). The reactivity of 3a toward a variety of unsaturated substrates: PhCCPh, di- t Bu-imidazol-2-ydene, PhN3, and Ph2CNN has been examined to probe the electrophilic (or nucleophilic) character of the low-coordinate P(I) site. In all cases reactions occur exclusively at the phosphinidene phosphorus atom, without CO displacement, affording examples of P-coordinated phosphirene [CpV(CO)3{P(N i Pr2)CPhCPh}] (7), abnormal NCN carbene adduct [CpV(CO)3{P(N i Pr2)-4-cyclo-C3H2-1,3-(N t Bu)2)}] (8), diazaphosphaimine [CpV(CO)3{P(N i Pr2)N−NCPh2}] (12), and P-coordinated phosphaimine [CpV(CO)3{P(N i Pr2)NPh}] (14) complexes. The η1-phosphaimine complexes 12 and 14 lose carbon monoxide to yield derivatives [CpV(CO)2{P(N i Pr2)N−NCPh2}] (9) and [CpV(CO)2{P(N i Pr2)NPh}] (15), which contain η2-(P,N)-coordinated phosphaimine ligands. An η3-(P,N,N)-bound phosphaimine ligand is present in an isomer of 9, namely, [CpV(CO)2{P(N i Pr2)N−NCPh2}], 13. Complexes 3a, 7, 8, 9, 14, and 15 have been characterized by X-ray crystallography.

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Section: ' Introductionmentioning

confidence: 99%

Section: ' Introductionmentioning

confidence: 99%

Section: ' Introductionmentioning

confidence: 99%

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Synthesis and Structural Characterization of the First Thermally Stable, Neutral, and Electrophilic Phosphinidene Complexes of Vanadium

et al. 2011

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“…A solution of 1b (600 mg, 1.98 mmol) in THF (10 mL) was added dropwise to a stirred suspension of Ph 3 C·BF 4 (655 mg, 1.98 mmol) in THF (10 mL) and stirred at room temperature for 2 h. The resultant white precipitate was collected by filtration, washed with diethyl ether (10 mL) and dried in vacuo to afford 2b (580 mg, 1.49 mmol, 75%) as a fine white powder. Crystals suitable for single crystal X-ray diffraction were grown from slow diffusion of diethyl ether into a concentrated solution of 2b in CDCl 3 …”

Section: Instrumentationmentioning

confidence: 99%

“…Transition metal stabilised phosphanylidene-σ 4 -phosphoranes (R 3 P=P(R)→ML n ) were first synthesised by Mathey and co-workers in 1990 [1] and have received attention as "phosphaWittig" reagents for the generation of P=C bonds, in which they act as phosphinidene (R-P) transfer reagents. [2][3][4][5][6] Free phosphanylidene-σ 4 -phosphoranes are rather reactive species, with only a handful of published examples where the compound is stabilised by extremely electron withdrawing substituents, [7,8] steric shielding, [9][10][11] or the combination of a rigid backbone and steric shielding. [12] Low co-ordinate arsenic chemistry is significantly less studied than that of phosphorus, with most attention being focused on arsaalkenes (R 2 C=AsR'), diarsenes (RAs=AsR), [13][14][15][16] and phosphine-and carbene-stabilised cationic species.…”

Section: Introductionmentioning

confidence: 99%

Hydride Abstraction and Deprotonation – an Efficient Route to Low Coordinate Phosphorus and Arsenic Species

et al. 2015

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Treatment of Acenap(PiPr 2 )(EH 2 ) (Acenap = acenaphthene-5,6-diyl; 1a, E = As; 1b, E = P) with Ph 3 C·BF 4 resulted in hydride abstraction to give [Acenap(PiPr 2 )(EH)][BF 4 ] (2a, E = As; 2b, E = P). These represent the first structurally characterised phosphino/arsino-phosphonium salts with secondary arsine/phosphine groups, as well as the first example of a Lewis base stabilised primary arsenium cation. Compounds 2a and 2b were deprotonated with NaH to afford low co-ordinate species Acenap(PiPr 2 )(E) (3a, E = As; 3b, E = P). This provides an alternative and practical synthetic pathway to the phosphanylidene-σ 4 -phosphorane 3b and provides mechanistic insight into the formation of arsanylidene-σ 4 -phosphorane 3a, indirectly supporting the hypothesis that the previously reported dehydrogenation of 1a occurs via an ionic mechanism.

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Low‐Oxidation‐State Main Group CompoundsUpdate based on the original article by Charles L. B. Macdonald and Bobby D. Ellis, Encyclopedia of Inorganic Chemistry Second Edition, © 2005, John Wiley & Sons, Ltd.

Macdonald

Ellis

Swidan

2012

Encyclopedia of Inorganic and Bioinorganic Chemistry

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The synthesis and chemistry of compounds containing groups 1, 2, and 13‐15 elements in unusually low oxidation states or valence states is presented. In general, the oxidation or valence state of an element influences the chemistry of the compounds in which the atom is found. For the main group elements, compounds containing elements in lower‐than‐usual oxidation or valence states exhibit significantly different structural features, modes of bonding, and chemistry than is observed for compounds containing the element in a more typical oxidation state. The elements of the s‐block form a limited number of low‐oxidation‐state compounds and the elements of groups 16‐18 are generally found in the lowest available oxidation state. Thus, this article provides an overview of the following classes of low‐valent main group species: the chemistry of group 2 elements in the +1 oxidation state, the chemistry of group 13 elements in oxidation states lower than +3, the chemistry of group 14 elements in oxidation states lower than +2, and the chemistry of the group 15 elements in oxidation states lower than +3. Numerous exemplary modes of reactivity are presented, and the utility of some low‐oxidation‐state compounds as catalysts or precursors to materials is acknowledged.

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Nucleophilic Phosphinidene Complexes: Access and Applicability

Cited by 212 publications

References 127 publications

Synthesis and Structural Characterization of the First Thermally Stable, Neutral, and Electrophilic Phosphinidene Complexes of Vanadium

Synthesis and Structural Characterization of the First Thermally Stable, Neutral, and Electrophilic Phosphinidene Complexes of Vanadium

Hydride Abstraction and Deprotonation – an Efficient Route to Low Coordinate Phosphorus and Arsenic Species

Low‐Oxidation‐State Main Group CompoundsUpdate based on the original article by Charles L. B. Macdonald and Bobby D. Ellis, Encyclopedia of Inorganic Chemistry Second Edition, © 2005, John Wiley & Sons, Ltd.

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