Threshold Collision‐Induced Dissociation of Hydrated Magnesium: Experimental and Theoretical Investigation of the Binding Energies for Mg2+(H2O)x Complexes (x=2–10)

Carl, Damon R.; Armentrout, P. B.

doi:10.1002/cphc.201200860

Cited by 32 publications

(13 citation statements)

References 67 publications

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“…12,13,65 The water binding energies on the bare Mg 2+ (H 2 O) n=3=10 clusters have been reported to fall rapidly after completion of the first hydration shell at n = 6, converging on a value around 4000 cm −1 by n = 10, which is approaching the photon energy of the free OH stretching bands in question. 56,66−70 Although not definitive because of these experimental limitations, the data are most consistent with the 11th water molecule starting the onset of the second hydration shell around one of the Mg 2+ ions, which is consistent with the expectation that this form corresponds to the global minimum.…”

Section: Observation Of Symmetrical Hydration Insupporting

confidence: 81%

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO₄Mg(H₂O)_n=4–11]²⁺ Clusters

et al. 2015

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Elucidation of the molecular-level mechanics underlying the dissolution of salts is one of the long-standing, fundamental problems in electrolyte chemistry. Here we follow the incremental structural changes that occur when water molecules are sequentially added to the ternary [MgSO4Mg](2+) ionic assembly using cryogenic vibrational predissociation spectroscopy of the cold, mass-selected [MgSO4Mg(H2O)n=4-11](2+) cluster ions. Although the bare [MgSO4Mg](2+) ion could not be prepared experimentally, its calculated minimum energy structure corresponds to a configuration where the two Mg(2+) ions attach on opposite sides of the central SO4(2-) ion in a bifurcated fashion to yield a D2d symmetry arrangement. Analysis of the observed spectral patterns indicate that water molecules preferentially attach to the flanking Mg(2+) ions for the n ≤ 7 hydrates, which results in an incremental weakening of the interaction between the ions. Water molecules begin to interact with the sequestered SO4(2-) anion promptly at n = 8, where changes in the band pattern clearly demonstrate that the intrinsic bifurcated binding motif among the ions evolves into quasilinear Mg(2+)-O-S arrangements as water molecules H-bond to the now free SO groups. Although condensed-phase MgSO4 occurs with a stable hexahydrate in which water molecules lie between the ion pairs, addition of a sixth water molecule to one of the Mg(2+) ions in the n = 11 cluster occurs with the onset of the second hydration shell such that the cation remains coordinated to one of the SO4(2-) oxygen atoms.

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Section: Observation Of Symmetrical Hydration Insupporting

confidence: 81%

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO₄Mg(H₂O)_n=4–11]²⁺ Clusters

et al. 2015

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“…Specifically, coordination numbers and sequential binding energies of water molecules have been previously determined by collision-induced-dissociation mass spectrometry (CID-MS) for the singly charged transition metals Ti-Cu 9 as well as for Ca 2+ , Mg 2+ , and Fe 2+ , and Zn 2+ . [10][11][12][13][14] Additionally, structures of hydrated singly and doubly charged alkali and transition metal clusters have been very well characterized by photodissociation spectroscopy. [15][16][17][18][19][20][21][22][23][24][25][26] Building on these results of solvated metal ions, we extend our study of the [MOH] + species to larger clusters to probe the effect of solvation on the M-OH charge transfer as well as to determine how the coordination sphere is influenced by the charged hydroxide ligand.…”

Section: Introductionmentioning

confidence: 99%

Coordination structure and charge transfer in microsolvated transition metal hydroxide clusters [MOH]⁺(H₂O)_1–4

Marsh

Voss

Zhou

et al. 2015

Phys. Chem. Chem. Phys.

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Infrared vibrational predissociation spectra of transition metal hydroxide clusters, [MOH](+)(H2O)1-4·D2 with M = Mn, Fe, Co, Ni, Cu, and Zn, are presented and analyzed with the aid of density functional theory calculations. For the [MnOH](+), [FeOH](+), [CoOH](+) and [ZnOH](+) species, we find that the first coordination shell contains three water molecules and the four ligands are arranged in a distorted tetrahedral geometry. [CuOH](+) can have either two or three water molecules in the first shell arranged in a planar arrangement, while [NiOH](+) has an octahedral ligand geometry with the first shell likely closed with five water molecules. Upon closure of the first coordination shell, characteristic stretch frequencies of hydrogen-bonded OH in the 2500-3500 cm(-1) region are used to pinpoint the location of the water molecule in the second shell. The relative energetics of different binding sites are found to be metal dependent, dictated by the first-shell coordination geometry and the charge transfer between the hydroxide and the metal center. Finally, the frequency of the hydroxide stretch is found to be sensitive to the vibrational Stark shift induced by the charged metal center, as observed previously for the smaller [MOH](+)(H2O) species. Increasing solvation modulates this frequency by reducing the extent of the charge transfer while elongating the M-OH bond.

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“…The more restricted CN of the Mg 2+ has previously been attributed to the smaller ion size [39,107,108], whereas the larger size of the Ca 2+ ion has been linked to weaker inner ion-solvent interactions in retrospect to that of the hydrated Mg 2+ ion [51]. As shown by Tables 3 and 5, the k a cum values of explicitly hydrated systems, based upon inner ionsolvent interactions, are larger for [Mg(H 2 O) n ] 2+ (n = 1-6) (1-6) clusters in comparison to that of their Ca 2+ counterparts by differences of 0.601 to 1.341 mdyn/Å (i.e., 1a-6a in 2).…”

Section: Resultsmentioning

confidence: 97%

Assessing the Intrinsic Strengths of Ion–Solvent and Solvent–Solvent Interactions for Hydrated Mg2+ Clusters

2021

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Information resulting from a comprehensive investigation into the intrinsic strengths of hydrated divalent magnesium clusters is useful for elucidating the role of aqueous solvents on the Mg2+ ion, which can be related to those in bulk aqueous solution. However, the intrinsic Mg–O and intermolecular hydrogen bond interactions of hydrated magnesium ion clusters have yet to be quantitatively measured. In this work, we investigated a set of 17 hydrated divalent magnesium clusters by means of local vibrational mode force constants calculated at the ωB97X-D/6-311++G(d,p) level of theory, where the nature of the ion–solvent and solvent–solvent interactions were interpreted from topological electron density analysis and natural population analysis. We found the intrinsic strength of inner shell Mg–O interactions for [Mg(H2O)n]2+ (n = 1–6) clusters to relate to the electron density at the bond critical point in Mg–O bonds. From the application of a secondary hydration shell to [Mg(H2O)n]2+ (n = 5–6) clusters, stronger Mg–O interactions were observed to correspond to larger instances of charge transfer between the lp(O) orbitals of the inner hydration shell and the unfilled valence shell of Mg. As the charge transfer between water molecules of the first and second solvent shell increased, so did the strength of their intermolecular hydrogen bonds (HBs). Cumulative local vibrational mode force constants of explicitly solvated Mg2+, having an outer hydration shell, reveal a CN of 5, rather than a CN of 6, to yield slightly more stable configurations in some instances. However, the cumulative local mode stretching force constants of implicitly solvated Mg2+ show the six-coordinated cluster to be the most stable. These results show that such intrinsic bond strength measures for Mg–O and HBs offer an effective way for determining the coordination number of hydrated magnesium ion clusters.

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Threshold Collision‐Induced Dissociation of Hydrated Magnesium: Experimental and Theoretical Investigation of the Binding Energies for Mg²⁺(H₂O)_x Complexes (x=2–10)

Cited by 32 publications

References 67 publications

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO₄Mg(H₂O)_n=4–11]²⁺ Clusters

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO₄Mg(H₂O)_n=4–11]²⁺ Clusters

Coordination structure and charge transfer in microsolvated transition metal hydroxide clusters [MOH]⁺(H₂O)_1–4

Assessing the Intrinsic Strengths of Ion–Solvent and Solvent–Solvent Interactions for Hydrated Mg2+ Clusters

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Threshold Collision‐Induced Dissociation of Hydrated Magnesium: Experimental and Theoretical Investigation of the Binding Energies for Mg2+(H2O)x Complexes (x=2–10)

Cited by 32 publications

References 67 publications

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO4Mg(H2O)n=4–11]2+ Clusters

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO4Mg(H2O)n=4–11]2+ Clusters

Coordination structure and charge transfer in microsolvated transition metal hydroxide clusters [MOH]+(H2O)1–4

Assessing the Intrinsic Strengths of Ion–Solvent and Solvent–Solvent Interactions for Hydrated Mg2+ Clusters

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Threshold Collision‐Induced Dissociation of Hydrated Magnesium: Experimental and Theoretical Investigation of the Binding Energies for Mg²⁺(H₂O)_x Complexes (x=2–10)

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO₄Mg(H₂O)_n=4–11]²⁺ Clusters

Vibrational Signatures of Solvent-Mediated Deformation of the Ternary Core Ion in Size-Selected [MgSO₄Mg(H₂O)_n=4–11]²⁺ Clusters

Coordination structure and charge transfer in microsolvated transition metal hydroxide clusters [MOH]⁺(H₂O)_1–4