Cage Rearrangements in Dodecanuclear Co–Pt Dicarbido Clusters Promoted by Redox Reactions

Femoni, Cristina; Iapalucci, Maria Carmela; Longoni, Giuliano; Zacchini, Stefano; Fedi, Serena; Biani, Fabrizia Fabrizi de

doi:10.1002/ejic.201101386

Cited by 11 publications

(9 citation statements)

References 30 publications

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“…Such a suggestion is further implemented by electrochemical studies, which clearly point out that [H 2 Ni 22 Co 6 C 6 (CO) 36 ] 4– and [HNi 22 Co 6 C 6 (CO) 36 ] 5– display different voltammetric profiles. If they were the same species in a different oxidation state, they would have, conversely, shown the same electrochemical behavior, as previously discussed. ,− In particular, [H 2 Ni 22 Co 6 C 6 (CO) 36 ] 4– displays two reduction processes with features of chemical reversibility ( E °′ 4–/5– = −0.533 V; E °′ 5–/6– = −0.833 V, in acetone), whereas [HNi 22 Co 6 C 6 (CO) 36 ] 5– displays three reductions ( E °′ 5–/6– = −0.961 V; E °′ 6–/7– = −1.293 V; E °′ 7–/8– = −1.666 V, in CH 3 CN). Therefore, the changes in ν(CO) reported in Scheme cannot be due to redox reactions.…”

Section: Resultsmentioning

confidence: 57%

“…In addition, joined electrochemical and chemical experiments result as being the only tools available to elucidate the polyhydride nature of such large carbonyl clusters, since their hydride atoms are 1 H NMR silent. This point has already been discussed in the literature, even if a satisfactory explanation of this phenomenon is still missing. ,− …”

Section: Discussionmentioning

confidence: 75%

“…We have recently discussed the problems of detecting hydrides in high-nuclearity carbonyl clusters, showing that above a nuclearity of ca. 22 all 1 H NMR resonances disappear since they become so broad as to get blurred in the baseline of the spectrum. ,− Thus, as already reported, the hydride nature of large metal carbonyl clusters can be only indirectly inferred from joined chemical and electrochemical experiments.…”

Section: Resultsmentioning

confidence: 88%

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Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H_6–nNi₂₂Co₆C₆(CO)₃₆]ⁿ⁻(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni₉CoC₂(CO)_16–x]^3–(x= 0, 1)

et al. 2012

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The reaction of [Ni 10 C 2 (CO) 16 ] 2− with Co 3 (μ 3 -CCl)(CO) 9 results in the new bimetallic Ni−Co hexacarbido carbonyl clusters [H 6−n Ni 22 Co 6 C 6 (CO) 36 ] n− (n = 3−6), which possess polyhydride nature and can be interconverted by means of acid−base reactions. The tetra-anion [H 2 Ni 22 Co 6 C 6 (CO) 36 ] 4− and the hexa-anion [Ni 22 Co 6 C 6 (CO) 36 ] 6− have been isolated in a crystalline state and structurally characterized via X-ray crystallography. The six carbide atoms are lodged into Ni 7 CoC square antiprismatic cages. Addition of strong bases to [Ni 22 Co 6 C 6 (CO) 36 ] 6− affords mixtures of the monoacetylides [Ni 9 CoC 2 (CO) 16 ] 3− and [Ni 9 CoC 2 (CO) 15 ] 3− , which have been cocrystallized as [NEt 4 ] 3 [Ni 9 CoC 2 (CO) 16−x ] (x = 0.58−0.84) salts, displaying tightly bonded interstitial C 2 units.

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Section: Resultsmentioning

confidence: 57%

Section: Discussionmentioning

confidence: 75%

Section: Resultsmentioning

confidence: 88%

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Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H_6–nNi₂₂Co₆C₆(CO)₃₆]ⁿ⁻(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni₉CoC₂(CO)_16–x]^3–(x= 0, 1)

et al. 2012

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“…The C 2 ‐acetylide fragment of [Co 4 Pd 4 C 2 (PPh 3 ) 4 (CO) 10 Cl] − is semiexposed in view of the fact that the metal cage is rather open. It must be remarked that several homoleptic MCCs containing fully interstitial C 2 units are known, with C–C contacts in the range 1.35–1.50 Å 17b, 29. Homoleptic MCCs containing semiexposed acetylide fragments are more rare.…”

Section: Resultsmentioning

confidence: 99%

Metal Segregation in Bimetallic CoPd Carbide Carbonyl Clusters: Synthesis, Structure, Reactivity and Electrochemistry of [H_6−nCo₂₀Pd₁₆C₄(CO)₄₈]ⁿ⁻ (n=3–6)

et al. 2013

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Nanometric Coï£¿Pd bimetallic [H6-nCo 20Pd16C4(CO)48]n- (n=3-6) tetracarbide carbonyl clusters have been prepared by redox condensation of [Co6C(CO)15]2- with [PdCl2(Et 2S)2]. The crystal structures of both the dihydride tetra-anion and monohydride penta-anion have been determined as their [NEt 4]4[H2Co20Pd16C 4(CO)48]×4 CH3COCH3 and [NMe3(CH2Ph)][NMe4]4[HCo 20Pd16C4(CO)48]×5 CH 3COCH3 salts, respectively. The two species are isostructural and their structures display a perfect segregation of the two metals. They are composed of a cubic close-packed (ccp) Pd16 core stabilised on its surface by four {Co5C(CO)12} organometallic fragments. Their polyhydride nature has been corroborated by the study of their reactions with acids and bases, and confirmed by electrochemical studies. In addition, the reactions of [H2Co20Pd 16C4(CO)48]4- with Na/naphthalene and PPh3/CO allowed the isolation of other lower nuclearity homoleptic and heteroleptic clusters, that is, [H6-nCo 16Pd2C3(CO)28]n- (n=5, 6), [Co4Pd2C(CO)11(PPh3) 2], [Co2Pd5C(CO)8(PPh 3)5], and [Co4Pd4C 2(PPh3)4(CO)10Cl]-. [H6-nCo16Pd2C3(CO) 28]n- (n=5, 6) represent the first homoleptic metal-carbonyl clusters containing three interstitial carbide atoms. Kept apart: Bimetallic nanometric Coï£¿Pd tetracarbide carbonyl clusters have been prepared by redox condensation. Their crystal structures, in which a cubic close-packed (ccp) Pd16 core is stabilised by four Co 5C(CO)12 organometallic fragments, display a perfect segregation of the two metals (see figure

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“…Viewed another way, the encapsulated transition metal atoms have a full 18-electron shell: 10 e – from Ni 0 and 2 e – each from each neighboring main group atom in the square antiprismatic pocket. The structure of [Ni 2 @Sn 7 Bi 5 ] 3– is related to a family of carbide-centered transition metal–carbonyl clusters (e.g., [C 2 @Rh 12 (CO) 24 ] 2– ) − as well as structural motifs found in the solid state, such as in Ir 3 E 7 (E = Ge, Sn) and FeBi 2 . − …”

Section: Ternary Clustersmentioning

confidence: 99%

Intermetalloid and Heterometallic Clusters Combining p-Block (Semi)Metals with d- or f-Block Metals

et al. 2019

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Clusters have been the subject of intense investigations since their famous definition launched by Cotton in 1963, and the area has expanded ever since. One obvious development addresses the widening of the definition of what to call a cluster: from purely (transition) metal−metal linked assemblies, as per Cotton's early denomination, to nonmetal/metal clusters or purely nonmetal cages, like fullerenes, and even noncovalent aggregates such as water clusters. The other extension concerns the broadened spectrum of compositions within the aforementioned cluster types and their corresponding structures that range from trinuclear motifs to clusters with sizes in the range of the hemoglobin unit. This review article reports on one cluster family that has its origins in traditional Zintl anion chemistry but has undergone rapid development in recent years, namely, ligand-free clusters that combine main group and transition metal atoms. Depending on the position of the transition metal atom(s), one refers to such clusters as intermetalloid (endohedral) clusters or as a special type of heterometallic clusters. The predominant synthetic access makes use of soluble Zintl anions. Other pathways for their preparation include traditional solid state reactions of according element combinations or bottom-up syntheses employing low valent organo-main group element sources. This survey will shed light on all of these approaches, with an emphasis on the syntheses that employ soluble Zintl anion compounds. The article will give a comprehensive overview of the currently known compounds, their different synthesis protocols, and analytic techniques for determination of their compositions, structures, and further properties. Additionally, this survey will report peculiarities of bonding situations found within some of the cluster molecules, which were studied by means of sophisticated quantum chemical investigations.

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Cage Rearrangements in Dodecanuclear Co–Pt Dicarbido Clusters Promoted by Redox Reactions

Cited by 11 publications

References 30 publications

Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H_6–nNi₂₂Co₆C₆(CO)₃₆]ⁿ⁻(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni₉CoC₂(CO)_16–x]^3–(x= 0, 1)

Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H_6–nNi₂₂Co₆C₆(CO)₃₆]ⁿ⁻(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni₉CoC₂(CO)_16–x]^3–(x= 0, 1)

Metal Segregation in Bimetallic CoPd Carbide Carbonyl Clusters: Synthesis, Structure, Reactivity and Electrochemistry of [H_6−nCo₂₀Pd₁₆C₄(CO)₄₈]ⁿ⁻ (n=3–6)

Intermetalloid and Heterometallic Clusters Combining p-Block (Semi)Metals with d- or f-Block Metals

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Cage Rearrangements in Dodecanuclear Co–Pt Dicarbido Clusters Promoted by Redox Reactions

Cited by 11 publications

References 30 publications

Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H6–nNi22Co6C6(CO)36]n−(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni9CoC2(CO)16–x]3–(x= 0, 1)

Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H6–nNi22Co6C6(CO)36]n−(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni9CoC2(CO)16–x]3–(x= 0, 1)

Metal Segregation in Bimetallic CoPd Carbide Carbonyl Clusters: Synthesis, Structure, Reactivity and Electrochemistry of [H6−nCo20Pd16C4(CO)48]n− (n=3–6)

Intermetalloid and Heterometallic Clusters Combining p-Block (Semi)Metals with d- or f-Block Metals

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Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H_6–nNi₂₂Co₆C₆(CO)₃₆]ⁿ⁻(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni₉CoC₂(CO)_16–x]^3–(x= 0, 1)

Bimetallic Nickel–Cobalt Hexacarbido Carbonyl Clusters [H_6–nNi₂₂Co₆C₆(CO)₃₆]ⁿ⁻(n= 3–6) Possessing Polyhydride Nature and Their Base-Induced Degradation to the Monoacetylide [Ni₉CoC₂(CO)_16–x]^3–(x= 0, 1)

Metal Segregation in Bimetallic CoPd Carbide Carbonyl Clusters: Synthesis, Structure, Reactivity and Electrochemistry of [H_6−nCo₂₀Pd₁₆C₄(CO)₄₈]ⁿ⁻ (n=3–6)