Reversible Binding of Dihydrogen in Multimetallic Complexes

Weller, Andrew S.; McIndoe, J. Scott

doi:10.1002/ejic.200700661

Cited by 54 publications

(40 citation statements)

References 98 publications

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“…16 It is well-established in mononuclear iron-hydride complexes. 34 In each of these cases, an open coordination site is required to bind H 2 in an η 2 binding mode.…”

Section: Discussionmentioning

confidence: 99%

Synthesis, Spectroscopy, and Hydrogen/Deuterium Exchange in High-Spin Iron(II) Hydride Complexes

et al. 2014

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Very few hydride complexes are known in which the metals have a high-spin electronic configuration. We describe the characterization of several high-spin iron(II) hydride/deuteride isotopologues and their exchange reactions with one another and with H2/D2. Though the hydride/deuteride signal is not observable in NMR spectra, the choice of isotope has an influence on the chemical shifts of distant protons in the dimers through the paramagnetic isotope effect on chemical shift. This provides the first way to monitor the exchange of H and D in the bridging positions of these hydride complexes. The rate of exchange depends on the size of the supporting ligand, and this is consistent with the idea that H2/D2 exchange into the hydrides occurs through the dimeric complexes rather than through a transient monomer. The understanding of H/D exchange mechanisms in these high-spin iron hydride complexes may be relevant to postulated nitrogenase mechanisms.

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“…16 It is well-established in mononuclear iron-hydride complexes. 34 In each of these cases, an open coordination site is required to bind H 2 in an η 2 binding mode.…”

Section: Discussionmentioning

confidence: 99%

Synthesis, Spectroscopy, and Hydrogen/Deuterium Exchange in High-Spin Iron(II) Hydride Complexes

et al. 2014

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“…The widespread use of hydrogen is hampered due to the challenge of safely storing and transporting it in its natural gaseous state 1. 2 Notwithstanding the issue of H % weight content,3 metal hydrides have long attracted attention as a storage medium for hydrogen, which can subsequently be released by heating or via irradiation with light 4…”

Section: Introductionmentioning

confidence: 99%

“…[1,2] Notwithstanding the issue of H % weight content, [3] metal hydrides have long attracted attention as a storage medium for hydrogen, which can subsequently be released by heating or via irradiation with light. [4] Silver hydrides are key intermediates in a number of reactions involving organic substrates [5] and several silver hydrides have been recently isolated and structurally characterised by X-ray crystallography. [6] In one such study, hydrogen evolution from [(LAg) 2 H] + (where L = N-heterocyclic carbene ligand 1,3bis(2,6-diisopropylphenyl)imidazolin-2-ylidene) was observed, but the precise mechanism for H 2 formation is unknown.…”

Section: Introductionmentioning

confidence: 99%

Formation and Characterisation of the Silver Hydride Nanocluster Cation [Ag₃H₂((Ph₂P)₂CH₂)]⁺ and Its Release of Hydrogen

Girod

Krstić

Antoine

et al. 2014

Chemistry A European J

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Multistage mass spectrometry and density functional theory (DFT) were used to characterise the small silver hydride nanocluster, [Ag3 H2 L](+) (where L=(Ph2 P)2 CH2 ) and its gas-phase unimolecular chemistry. Collision-induced dissociation (CID) yields [Ag2 HL](+) as the major product while laser-induced dissociation (LID) proceeds via H2 formation and subsequent release from [Ag3 H2 L](+) , giving rise to [Ag3 L](+) as the major product. Deuterium labelling studies on [Ag3 D2 L](+) prove that the source of H2 is from the hydrides and not from the ligand. Comparison of TD-DFT absorption patterns obtained for the optimised structures with action spectroscopy results, allows assignment of the measured features to structures of precursors and products. Molecular dynamics "on the fly" reveal that AgH loss is favoured in the ground state, but H2 formation and loss is preferred in the first excited state S1 , in agreement with CID and LID experimental findings. This indicates favourable photo-induced formation of H2 and subsequent release from [Ag3 H2 L](+) , an important finding in context of metal hydrides as a hydrogen storage medium, which can subsequently be released by heating or irradiation with light.

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“…Finally, it may be interesting to note that, whereas the above-mentioned remarkable examples of hindered molecular clusters, kinetically stabilised by bulky phosphines, de- scribed by Weller [15,17] and Adams [18] are able to oxidatively add (reversibly) a large number of H 2 molecules, our {Pt 6 }A 2 clusters activate the H À H bond and the C À H bond of DME by heterolytic splitting. The extension of this procedure to other ethers and to other CÀH bonds, and the possible applications to homogeneous catalysis [19e, 30] are currently under investigation.…”

Section: A C H T U N G T R E N N U N G (Pr 3 ) 2 ] and [Ptha C H T U mentioning

confidence: 97%

“…Moreover, it must be remembered that thermally unstable dihydrogen complexes, with two bulky phosphorus ligands cis to the Pt(H 2 ) site, have been observed previously and characterised in detail in squareplanar mononuclear platinum(II) complexes, [8a, 14] but nonclassical bonding of dihydrogen in molecular clusters of transition metals has been suggested rarely and only on the basis of indirect evidence. [15] Trapping one or more kinetic intermediate (and the nature of the trapped species) in the complex pathway from 2 to 4 may depend strongly on various parameters, especially on the solvent and on the acid strength of HA. Unfortunately, as mentioned above, following the reaction with TfOH at low temperatures in apolar solvents turned out to be impossible and, therefore, we decided to investigate the (slower) reaction with weaker acids.…”

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confidence: 99%

Proton‐Transfer Reactions on Hexanuclear Platinum Clusters: Reversible Heterolytic Cleavage of H₂ and CH Activation Affording a Linear, Cluster‐Containing Polymer

Leoni¹,

Marchetti²,

Bonuccelli³

et al. 2010

Chemistry A European J

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The hexanuclear cluster {Pt(6)}H(2) (2) contains a sterically hindered and chemically stable {Pt(6)} = Pt(6)(mu-PtBu(2))(4)(CO)(4) core, with the six metals forming an edge-bridged tetrahedron. The two hydrides are the reactive sites of the cluster and lie on opposite sides of the cluster, terminally bonded to the two "apical" edge-bridging platinum centres. Indeed, cluster 2 reacts with acids of different acidity (HA = CF(3)SO(3)H, HBF(4), p-CH(3)-C(6)H(4)-SO(3)H, CF(3)COOH, PhCOOH and CH(3)COOH), affording, after evolution of two equivalents of dihydrogen, the corresponding anion-substituted clusters {Pt(6)}A(2) (4). We suggest that the reaction proceeds through a mechanism similar to the one generally accepted for the analogous protonation of mononuclear hydrides, with some of the intermediates partially characterised at low temperature. Interestingly, the reverse reaction, the heterolytic splitting of H(2) by clusters 4, occurs readily under mild conditions. The anions in clusters 4a and 4b (4a: A = CF(3)SO(3), 4b: A = BF(4)) are bonded in the solid state but very easily dissociate in solution and may be substituted under mild conditions by weak ligands, such as CH(2)Cl(2) or CH(3)CN. With dialkyl ethers, the reaction proceeds further with the heterolytic splitting of a C-H bond of the ethereal ligand. This process allowed us to isolate the polymer [{Pt(6)}(CH(2)OCH(2)CH(2)OCH(2))](x) (8), in which the {Pt(6)} cluster units are connected by insulating spacers arising from dimethoxyethane. The results of single-crystal X-ray diffraction studies on 4a and 8 are also reported.

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Reversible Binding of Dihydrogen in Multimetallic Complexes

Cited by 54 publications

References 98 publications

Synthesis, Spectroscopy, and Hydrogen/Deuterium Exchange in High-Spin Iron(II) Hydride Complexes

Synthesis, Spectroscopy, and Hydrogen/Deuterium Exchange in High-Spin Iron(II) Hydride Complexes

Formation and Characterisation of the Silver Hydride Nanocluster Cation [Ag₃H₂((Ph₂P)₂CH₂)]⁺ and Its Release of Hydrogen

Proton‐Transfer Reactions on Hexanuclear Platinum Clusters: Reversible Heterolytic Cleavage of H₂ and CH Activation Affording a Linear, Cluster‐Containing Polymer

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Reversible Binding of Dihydrogen in Multimetallic Complexes

Cited by 54 publications

References 98 publications

Synthesis, Spectroscopy, and Hydrogen/Deuterium Exchange in High-Spin Iron(II) Hydride Complexes

Synthesis, Spectroscopy, and Hydrogen/Deuterium Exchange in High-Spin Iron(II) Hydride Complexes

Formation and Characterisation of the Silver Hydride Nanocluster Cation [Ag3H2((Ph2P)2CH2)]+ and Its Release of Hydrogen

Proton‐Transfer Reactions on Hexanuclear Platinum Clusters: Reversible Heterolytic Cleavage of H2 and CH Activation Affording a Linear, Cluster‐Containing Polymer

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Formation and Characterisation of the Silver Hydride Nanocluster Cation [Ag₃H₂((Ph₂P)₂CH₂)]⁺ and Its Release of Hydrogen

Proton‐Transfer Reactions on Hexanuclear Platinum Clusters: Reversible Heterolytic Cleavage of H₂ and CH Activation Affording a Linear, Cluster‐Containing Polymer