Coinage Metal Superatomic Cores: Insights into Their Intrinsic Stability and Optical Properties from Relativistic DFT Calculations

Gam, Franck; Páez‐Hernández, Dayán; Arratia‐Pérez, Ramiro; Liu, C. W.; Kahlal, Samia; Saillard, Jean Yves; Muñoz-Castro, Álvaro

doi:10.1002/chem.201701673

Cited by 26 publications

(39 citation statements)

References 95 publications

(213 reference statements)

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“…A Morokuma-Ziegler decomposition of the bonding energy [50][51][52] 58 In fact, in such bare metal clusters Ag behaves always a bit differently than Cu and Ag, because the periodical trend is likely to be counterbalanced by the relativistic effects. 58 Table 1), whereas that of its (n + 1)p σ AO remains lower than 0.1 e in the three clusters. The less important e and t 1 contributions of the orbital interaction energy (Table 1) (Figure 1), each of the four Ni 6 (CO) 3 (µ-CO) 6 (µ -CO) units has local C 3v symmetry.…”

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confidence: 99%

[M₁₆Ni₂₄(CO)₄₀]^4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au₂₀ Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

et al. 2018

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Characterization of the tetrahedral Au 20 structure in the gas-phase remains as a major landmark in gold cluster chemistry, where further efforts to stabilize this bare 20-electron superatom in solution, to extend and understand its chemistry have failed so far. Here, we account for the structural, electronic and bonding properties of [M 16 Ni 24 (CO) 40 ] 4-(M = Cu, Ag, Au) observed in solution for gold and silver. Our results show a direct electronic relationship with Au 20 , owing that such species share a common tetrahedral [M 16 ] 4central core with a 1S 2 1P 6 1D 10 2S 2 jellium configuration. In the case of Au 20 , the [Au 16 ] 4core is capped by four Au + ions, whereas in [M 16 Ni 24 (CO) 40 ] 4it is capped by four Ni 6 (CO) 10 units. In both cases, the capping entities are full part of the superatom entity where appears that the free (uncapped) [M 16 ] 4species requires to be capped for further stabilization. It follows that the Ni 6 (CO) 10 units in [M 16 Ni 24 (CO) 40 ] 4should not be considered as external ligands as their bonding with the [M 16 ] 4core is mainly associated with a delocalization of the 20 jellium electrons onto the Ni atoms. Thus, the [M 16 Ni 24 (CO) 40 ] 4species can be seen as the solution version of tetrahedral M 20 clusters, encouraging experimental efforts to further develop the chemistry of such complexes as M(111) finite surface section structures, with M=Ag and Au and, and particularly promising with M=Cu. Furthermore, optical properties were simulated to assist future experimental characterization. Relevant computed data for [M 16 ] 4and [M 20 ] clusters (M=Cu, Ag, Au) of jellium configuration 1S 2 1P 6 1D 10 2S 2 , and Kohn-Sham jellium orbitals of [Au ] 4and [Au 20 ]. Major electronic absorption for [M 16 Ni 24 (CO) 40 ] 4-(M = Cu, Ag, Au) computed at the PBE and BP86 levels. This material is available free of charge via the Internet at http://pubs.acs.org.

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confidence: 99%

[M₁₆Ni₂₄(CO)₄₀]^4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au₂₀ Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

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“…The resulting shell structure in I exhibits 6‐ ve (Au + 8xAu‐q = 6‐ ve ; Pd/Pt + 8xAu‐q = 6‐ ve ), which are distributed in an 1S 2 1P x 2 1P y 2 shell structure, denoted as 1S 2 1P 4 for simplicity (Figure ). Owing to the oblate shape of the M@Au 8 core, the 1P z shell remains as a low‐lying unoccupied orbital, in contrast to spherical shape cluster (as the icosahedral [Au 13 ] 5+ core), depicting an almost degenerated 3‐fold 1P shell. Thus, in I , a 6‐ ve count is favored in contrast to the 8‐ ve .…”

Section: Resultsmentioning

confidence: 99%

Nature of mercury inclusion in intermediate 6‐valence electron [M@Au₈Hg_x(PPh₃)₈]ⁿ⁺ (M = Au, Pd, Pt; x = 0‐2) protected gold superatoms: Insights from relativistic density functional theory calculations

Quintana

Ocayo

Guajardo‐Maturana

et al. 2019

Int J of Quantum Chemistry

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Superatomic clusters offer useful templates displaying distinctive physical and chemical characteristics. Here, we explore the [M@Au 8 (PPh 3 ) 8 ] n+ (M = Au, n = 3; Pd, Pt, n = 2) robust framework to gain an understanding of the nature of the inclusion of mercury atoms at Au 4 faces, leading to [M@Au 8 Hg x (PPh 3 ) 8 ] n+ (x = 1, 2). Our results show a weak interaction of about 25 kcal mol −1 per Hg atom, which is mainly of electrostatic character, followed by orbital and London dispersion-type interactions. This weak interaction can be understood as the formation of host-guest species, for which the inherent electronic and optical properties of the [M@Au 8 (PPh 3 ) 8 ] cluster along the series do not vary to a large extent. This demonstrates that, in [M@Au 8 Hg x (PPh 3 ) 8 ], each Hg can be considered an inclusion atom rather than a dopant element, where the parent cluster is able to act as a Lewis acid host. Furthermore, the viable formation of such species can serve as useful examples to stimulate future experimental characterization of inclusion complexes involving related superatomic structures with available open faces. K E Y W O R D S clusters, gold clusters, Lewis-acid, mercury

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“…The intrinsic stabilities of the bare superatomic cores usually found in ligand‐protected clusters have been explored by Gam, for M 4 2+ , M 13 5+ , M 32 14+ , and M 43 9+ , expanding the study to the whole coinage metal group. In addition, the specific optical spectrum patterns, vibrational properties and spin‐orbit coupling effects for each isolated superatomic core was given.…”

Section: Thiolate‐protected Gold Clustersmentioning

confidence: 99%

Bonding and properties of superatoms. Analogs to atoms and molecules and related concepts from superatomic clusters

Tlahuice‐Flores

Muñoz-Castro

2018

Int J of Quantum Chemistry

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Expanding the versatility of well‐defined clusters is a fundamental issue in the design of functional nanostructures. In this sense, the concept of super atoms allows us to gain a deeper understanding and rationalization of the different properties of metallic clusters by invoking more familiar aspects. Recently, the super atoms appear to be intimately connected to other relevant tools of great chemical significance which enhance a rational design of superatomic clusters mimicking more complex structures and networks. Here, we expect to account for the research efforts from Latin American groups in the field, highlighting their valuable contribution to superatomic and related clusters.

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Coinage Metal Superatomic Cores: Insights into Their Intrinsic Stability and Optical Properties from Relativistic DFT Calculations

Cited by 26 publications

References 95 publications

[M₁₆Ni₂₄(CO)₄₀]^4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au₂₀ Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

[M₁₆Ni₂₄(CO)₄₀]^4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au₂₀ Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

Nature of mercury inclusion in intermediate 6‐valence electron [M@Au₈Hg_x(PPh₃)₈]ⁿ⁺ (M = Au, Pd, Pt; x = 0‐2) protected gold superatoms: Insights from relativistic density functional theory calculations

Bonding and properties of superatoms. Analogs to atoms and molecules and related concepts from superatomic clusters

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Coinage Metal Superatomic Cores: Insights into Their Intrinsic Stability and Optical Properties from Relativistic DFT Calculations

Cited by 26 publications

References 95 publications

[M16Ni24(CO)40]4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au20 Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

[M16Ni24(CO)40]4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au20 Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

Nature of mercury inclusion in intermediate 6‐valence electron [M@Au8Hgx(PPh3)8]n+ (M = Au, Pd, Pt; x = 0‐2) protected gold superatoms: Insights from relativistic density functional theory calculations

Bonding and properties of superatoms. Analogs to atoms and molecules and related concepts from superatomic clusters

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[M₁₆Ni₂₄(CO)₄₀]^4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au₂₀ Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

[M₁₆Ni₂₄(CO)₄₀]^4–: Coinage Metal Tetrahedral Superatoms as Useful Building Blocks Related to Pyramidal Au₂₀ Clusters (M = Cu, Ag, Au). Electronic and Bonding Properties from Relativistic DFT Calculations

Nature of mercury inclusion in intermediate 6‐valence electron [M@Au₈Hg_x(PPh₃)₈]ⁿ⁺ (M = Au, Pd, Pt; x = 0‐2) protected gold superatoms: Insights from relativistic density functional theory calculations