2008
DOI: 10.1039/b710506a
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Cubane and step-form structures of dilithium bis(aryloxy)phosphines

Abstract: The lithium complexes RP(3,5-tBu2C6H2OLi)2(THF)4, where R = Ph or i Pr, (R[OPO]Li2)2(THF)4, synthesized by reaction of the 2-bromo-4,6-di-tert-butylphenol with BuLi and the appropriate dichlorophosphine, possess solid state structures composed of lithium oxide tetragons arranged in a step-form or face sharing half-cubane arrangements. Incorporation of excess lithium aryloxide results in the formation of complexes that display an extended step-form structure, [Ph[OPO]Li2(ArOLi)]2, or a distorted cubane arrangem… Show more

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Cited by 21 publications
(31 citation statements)
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“…The observed 31 P NMR chemical shift at approximately -32 ppm from these experiments is comparable to those acquired with well-defined compounds prepared in DME or THF solutions. [18,20] Attempts to grow crystals of these solvent-free lithium complexes, however, led to amorphous precipitates, the 1 H NMR spectra of which are unfortunately featureless. Similar reactions were conducted in diethyl ether solutions, which also led to the clean formation of the anticipated dilithium derivative as indicated by 31 Ph and NaH in DME gave Na(HL Ph )(DME) 2 .…”
Section: Resultsmentioning
confidence: 99%
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“…The observed 31 P NMR chemical shift at approximately -32 ppm from these experiments is comparable to those acquired with well-defined compounds prepared in DME or THF solutions. [18,20] Attempts to grow crystals of these solvent-free lithium complexes, however, led to amorphous precipitates, the 1 H NMR spectra of which are unfortunately featureless. Similar reactions were conducted in diethyl ether solutions, which also led to the clean formation of the anticipated dilithium derivative as indicated by 31 Ph and NaH in DME gave Na(HL Ph )(DME) 2 .…”
Section: Resultsmentioning
confidence: 99%
“…[18,20] In this contribution, we describe the syntheses and structures of diethyl ether adducts of Li(HL Ph ) and Li 2 L Ph ; the structural motif of these molecules is notably distinct from those of Li 2 (L Ph )(DME) 2 [18] and {Li 2 (L Ph )(THF) 2 } 2 . [20] Utilization of the established Group 1 complexes of [L Ph ] 2-for the preparation of iron derivatives is also reported. Investigation of phenolate complexes of iron is intriguing in view of their relevance to metalloprotein chemistry.…”
Section: Introductionmentioning
confidence: 99%
“…[15] At erminally bonded phosphinidene ligand remains ak ey target in rare-earth metal chemistry,a lthough auranium complex of such aligand was reported recently. [16] Thechemistry of rare-earth metal complexes with arsenic donor ligands is almost entirely unexplored:arsenide (R 2 As À ) complexes are rare, [17][18][19][20][21][22] and arsinidene (RAs 2À )l igands are unknown in rare-earth metal chemistry.T he development of synthetic routes to rare-earth metal arsinidene complexes could lead to more novel reactivity,s uch as arsinidene transfer, and would also furnish new opportunities for using arsenic ligands to influence the electronic structure and magnetism of lanthanide(III) complexes.W ith these possibilities in mind, we now report the first example of arare-earth metal arsinidene complex.Our strategy involved the initial synthesis of ap rimary arsine complex of yttrium to establish the metal-arsenic bond, followed by deprotonation of the {YAsH 2 R} unit to give corresponding yttrium-arsenide and yttrium-arsinidene complexes.T hus,a dding one stoichiometric equivalent of mesitylarsine to Cp' 3 Yi nt oluene led to the formation of [Cp' 3 Y{As(H) 2 Mes}] (1)( Cp' = h 5 -C 5 H 4 Me,M es = mesityl), which was crystallized as colorless blocks in 88 %y ield (Scheme 1). To obtain the yttrium arsenide complex, 1 was dissolved in toluene and one equivalent of nBuLi was added.…”
mentioning
confidence: 99%
“…[15] At erminally bonded phosphinidene ligand remains ak ey target in rare-earth metal chemistry,a lthough auranium complex of such aligand was reported recently. [16] Thechemistry of rare-earth metal complexes with arsenic donor ligands is almost entirely unexplored:arsenide (R 2 As À ) complexes are rare, [17][18][19][20][21][22] and arsinidene (RAs 2À )l igands are unknown in rare-earth metal chemistry.T he development of synthetic routes to rare-earth metal arsinidene complexes could lead to more novel reactivity,s uch as arsinidene transfer, and would also furnish new opportunities for using arsenic ligands to influence the electronic structure and magnetism of lanthanide(III) complexes.W ith these possibilities in mind, we now report the first example of arare-earth metal arsinidene complex.…”
mentioning
confidence: 99%
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