All-Hydrocarbon-Ligated Superatomic Gold/Aluminum Clusters

Antsiburov, Ivan; Schütz, Max; Bühler, Raphael; Muhr, Maximilian; Stephan, Johannes; Gemel, Christian; Klein, Wilhelm; Kahlal, Samia; Saillard, Jean-Yves; Fischer, Roland A.

doi:10.1021/acs.inorgchem.3c03790

Cited by 4 publications

(1 citation statement)

References 52 publications

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“…Recently Au/Al alloy nanoclusters containing hydrides, have been reported. 33 Unfortunately, the disorder in the metallic framework precludes determining the position of the hydrides via single-crystal diffraction. However, IR spectroscopy and DFT calculation confirm the presence of hydrides.…”

Section: Hydrides As a One-negatively Charged Ligand Or Metallic Hydr...mentioning

confidence: 99%

Hydride-doped coinage metal superatoms and their catalytic applications

Chiu,

Liao,

Silalahi

et al. 2024

Nanoscale Horiz.

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Section: Hydrides As a One-negatively Charged Ligand Or Metallic Hydr...mentioning

confidence: 99%

Hydride-doped coinage metal superatoms and their catalytic applications

Chiu,

Liao,

Silalahi

et al. 2024

Nanoscale Horiz.

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A Mixed Aryl/Amide Complex of Iron(II)

Wolf,

Bühler,

Napoli

et al. 2024

Zeitschrift anorg allge chemie

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The combined incorporation of a labile and a stabilizing ligand in a metal‐organic precursor is of interest for the synthesis of low valent ligated (hetero)metallic clusters. The heteroleptic aryl/amide iron (II) complex [Fe2(Mes)2(BTSA)2] (1) was synthesized by equimolar mixing of [Fe2(Mes)4] with [Fe2(BTSA)4]. (VT)‐NMR‐, UV‐Vis‐ and SC‐XRD‐analysis combined with DFT calculations revealed a dimeric structure with terminal bis(trimethylsilyl)amide‐ and bridging mesityl‐ligands in solution and as well in the solid phase. The treatment of [Fe2(BTSA)4] with the carbenoid group 13 metallo‐ligand GaCp* is known to yield simply adducts. In contrast, monitoring the reactions of [Fe2(Mes)4] and [Fe2(Mes)2(BTSA)2] (1) with GaCp* by liquid injection field desorption mass spectrometry (LIFDI‐MS) suggest formation of a broader variety of bimetallic Fe‐Ga‐species with iron formally reduced to iron (I) or iron (0). However, the product distribution obtained using the heteroleptic compound 1 indicates combined reactivity of the homoleptic congeners by showing larger species with variations of Fe/Ga ratios towards the formation of Fe/Ga clusters. This blended behavior is assigned to the more labile mesityl ligand and the more stabilizing BTSA‐ligand.

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Metal–Metal Bonding in Late Transition-Metal [M₂L₅] Complexes: Exploring the Limits of the Isolobal Analogy between the CO and AlCp* Ligands

et al. 2023

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Late dinuclear transition-metal (especially group 10 and 11) homoleptic carbonyl complexes are elusive species and have so far not been isolated. A typical example is the 30-electron species [Ni2(CO)5], the structure and bonding of which is still debated. We show that, by using the AlCp* ligand (isolobal to CO), it is possible to isolate and fully characterize [Ni2(AlCp*)5] (1), which inspired us to revisit by DFT calculations, the bonding situation within [Ni2L5] (L = CO, AlCp*) and other isoelectronic species. The short Ni–Ni X-ray distance in 1 (2.270 Å) should not be attributed to the existence of a typical localized triple-bond between the metals, but rather to a strong through-bond interaction involving the three bridging ligands via their donating lone pairs and accepting π* orbitals. In contrast, in the isostructural 32-electron [Au2(AlCp*)5] (2) cluster an orbital with M–M antibonding and Al...Al bonding character is occupied, which is in accordance with the particularly long Au–Au distance (3.856 Å) and rather short Al...Al contacts between the bridging ligands (2.843 Å). This work shows that, unlike late transition-metal [M2(CO) x ] species, stable [M2(AlCp*) x ] complexes can be isolated, owing to the subtle differences between CO and AlCp*. We propose a similar approach for rationalizing the bonding in the emblematic 34 electron species [Fe2(CO)9].

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All-Hydrocarbon-Ligated Superatomic Gold/Aluminum Clusters

Cited by 4 publications

References 52 publications

Hydride-doped coinage metal superatoms and their catalytic applications

Hydride-doped coinage metal superatoms and their catalytic applications

A Mixed Aryl/Amide Complex of Iron(II)

Metal–Metal Bonding in Late Transition-Metal [M₂L₅] Complexes: Exploring the Limits of the Isolobal Analogy between the CO and AlCp* Ligands

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All-Hydrocarbon-Ligated Superatomic Gold/Aluminum Clusters

Cited by 4 publications

References 52 publications

Hydride-doped coinage metal superatoms and their catalytic applications

Hydride-doped coinage metal superatoms and their catalytic applications

A Mixed Aryl/Amide Complex of Iron(II)

Metal–Metal Bonding in Late Transition-Metal [M2L5] Complexes: Exploring the Limits of the Isolobal Analogy between the CO and AlCp* Ligands

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Metal–Metal Bonding in Late Transition-Metal [M₂L₅] Complexes: Exploring the Limits of the Isolobal Analogy between the CO and AlCp* Ligands