Fission barriers of doubly charged silver clusters

Krückeberg, S.; Dietrich, G.; Lützenkirchen, K.; Schweikhard, L.; Walther, Clemens; Ziegler, J.

doi:10.1007/s100530050415

Cited by 12 publications

(9 citation statements)

References 24 publications

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“…This is not the case for smaller Ag species. As previously observed, Ag 3 bound to tryptophan in TrpAg 3 + is singly charged. [11] The even smaller species Ag 2 2+ is not bound as a consequence of the electrostatic repulsion and the absence of valence electrons.…”

Section: Angewandte Chemiesupporting

confidence: 66%

“…) are not stable for n < 7, [3] stabilization can be provided by the environment. Indeed, the attachment of protective ligands such as complex chemical [4] or biomolecular [5,6] templates was used to stabilize multiply charged clusters.…”

Section: +mentioning

confidence: 94%

“…Small multiply charged systems, in particular silver clusters, have been studied extensively in the gas phase. [2,3] Although isolated metal clusters with double charge (e.g. Ag n…”

mentioning

confidence: 99%

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Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

et al. 2010

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Section: Angewandte Chemiesupporting

confidence: 66%

Section: +mentioning

confidence: 94%

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Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

et al. 2010

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Section: Cluster Dissociation and The Liquid-drop Modelmentioning

confidence: 93%

“…Brechignac et al explained this result by suggesting that instead of continuing to increase with increasing cluster size, the fission barrier height evolves in such a way as to stay competitive with evaporation as the cluster size increases [38]. The interpretation of the LE cluster dissociation results would be greatly facilitated by the measurement of the activation energies of evaporation and fission for these clusters as has been reported for multiply charged silver clusters [62].The liquid-drop model has been used previously to describe the asymmetric dissociation and charge partitioning of tetrameric streptavidin [30]. Homogeneous protein complexes of 2-6 monomer units have been shown to dissociate primarily by the ejection of a single subunit that removes 30 -50% of the total charge of the complex [29][30][31][32][33]35].…”

mentioning

confidence: 94%

Gas-phase dissociation pathways of multiply charged peptide clusters

Jurchen

García

Williams

2003

J. Am. Soc. Mass Spectrom.

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Numerous studies of cluster formation and dissociation have been conducted to determine properties of matter in the transition from the condensed phase to the gas phase using materials as diverse as atomic nuclei, noble gasses, metal clusters, and amino acids. Here, electrospray ionization is used to extend the study of cluster dissociation to peptides including leucine enkephalin with 7-19 monomer units and 2-5 protons, and somatostatin with 5 monomer units and 4 protons under conditions where its intramolecular disulfide bond is either oxidized or reduced. Evaporation of neutral monomers and charge separation by cluster fission are the competing dissociation pathways of both peptides. The dominant fission product for all leucine enkephalin clusters studied is a proton-bound dimer, presumably due to the high gas-phase stability of this species. The branching ratio of the fission and evaporation processes for leucine enkephalin clusters appears to be determined by the value of z 2 /n for the cluster where z is the charge and n the number of monomer units in the cluster. Clusters with low and high values of z 2 /n dissociate primarily by evaporation and cluster fission respectively, with a sharp transition between dissociation primarily by evaporation and primarily by fission measured at a z 2 /n value of ~0.5. The dependence of the dissociation pathway of a cluster on z 2 /n is similar to the dissociation of atomic nuclei and multiply charged metal clusters indicating that leucine enkephalin peptide clusters exist in a state that is more disordered, and possibly fluid, rather than highly structured in the dissociative transition state. The branching ratio, but not the dissociation pathway of [somatostatin 5 + 4H] 4+ is altered by the reduction of its internal disulfide bond indicating that monomer conformational flexibility plays a role in peptide cluster dissociation.Bulk properties of matter and the properties of isolated gas-phase atoms and molecules can have radically different characteristics in terms of structure, work function, ion solvation, etc. (for a review see reference [1]). One motivation behind cluster research is that the transitional characteristics between bulk and molecular properties can be discovered by studying intermediate states of matter. Investigators have explored a wide variety of materials, including charged droplets of various liquids [2,3], clusters of noble metals [4][5][6][7][8], metal-ligand clusters [1,[9][10][11], highly charged clusters of noble gasses [12,13], small molecules [14,15], and ultracold clusters of transition metals [16]. Recently, investigators have formed noncovalently bound clusters of biologically important molecules, including clusters of amino acids and small peptides [17][18][19][20][21][22][23][24][25][26][27][28], and have studied their dissociation processes [18,20,[26][27][28]. Multiply charged "clusters" of proteins consisting of multimeric, noncovalently associated protein complexes with a high degree of solution-phase structural specificity ...

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Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

et al. 2010

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Fission barriers of doubly charged silver clusters

Cited by 12 publications

References 24 publications

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

Gas-phase dissociation pathways of multiply charged peptide clusters

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

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Fission barriers of doubly charged silver clusters

Cited by 12 publications

References 24 publications

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag42+ as an Optical Marker for Monitoring Particle Growth

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag42+ as an Optical Marker for Monitoring Particle Growth

Gas-phase dissociation pathways of multiply charged peptide clusters

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag42+ as an Optical Marker for Monitoring Particle Growth

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Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth

Doubly Charged Silver Clusters Stabilized by Tryptophan: Ag₄²⁺ as an Optical Marker for Monitoring Particle Growth