A Gallium‐Substituted Distibene and an Antimony‐Analogue Bicyclo[1.1.0]butane: Synthesis and Solid‐State Structures

Tuscher, Lars; Ganesamoorthy, Chelladurai; Bläser, Dieter; Wölper, Christoph; Schulz, Stephan

doi:10.1002/anie.201502827

Cited by 68 publications

(63 citation statements)

References 125 publications

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“…1 and 4 show syn,syn configurations with the halogen atoms orienting toward the middle of the Ga-E-Ga skeleton. The Ga–Sb bond lengths in 1 [2.5899(4), 2.5909(3) Å] are comparable to those in [L(X)Ga] 2 Sb 4 [X = Cl 2.6008(13) Å, NMe 2 2.5975(5) Å] 33,36 , but shorter than in 2 [2.6265(11) Å], 3 [2.6979(2) Å], Ga-substituted distibenes [L(X)Ga] 2 Sb 2 [X = NMe 2 2.6477(3) Å, NMeEt 2.6433(6) Å, Cl 2.6461(2) Å] 33,36 , the sum of the covalent radii (Ga 1.24 Å; Sb 1.40 Å) 38 , as well as Lewis acid-base adducts R 3 Ga-SbR' 3 (2.84–3.02 Å) and heterocycles [R 2 GaSb(SiMe 3 ) 2 ] x ( x = 2, 3; 2.65–2.76 Å) 39 . The Ga–Bi bond lengths in 4 [2.6640(9), 2.6663(9) Å] agree well with those of [L(OSO 2 CF 3 )Ga] 2 Bi 2 (2.655(1) Å] 40 , but are shorter than those in [L(OC 6 F 5 )Ga] 2 Bi 2 [2.693(6) Å] 40 , L(Et)GaBiEt 2 [2.6959(3) Å] 41 , LGa(BiEt 2 ) 2 [2.6961(6) Å, 2.7303(10) Å] 32 and the sum of the covalent radii (Ga 1.24 Å; Bi 1.51 Å) 38 .…”

Section: Resultsmentioning

confidence: 71%

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From stable Sb- and Bi-centered radicals to a compound with a Ga=Sb double bond

et al. 2018

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Neutral stibinyl and bismuthinyl radicals are typically short-lived, reactive species. Here we show the synthesis and solid-state structures of two stable stibinyl [L(Cl)Ga]2Sb· 1 and bismuthinyl radicals [L(I)Ga]2Bi· 4, which are stabilized by electropositive metal centers. Their description as predominantly metal-centered radicals is consistent with the results of NMR, EPR, SQUID, and DFT studies. The Lewis-acidic character of the Ga ligands allow for significant electron delocalization of the Sb- and Bi- unpaired radical onto the ligand. Single-electron reduction of [L(Cl)Ga]2Sb· gave LGaSbGa(Cl)L 5, the first compound containing a Ga=Sb double bond. The π-bonding contribution is estimated to 9.56 kcal mol−1 by NMR spectroscopy. The bonding situation and electronic structure is analyzed by quantum mechanical computations, revealing significant π backdonation from the Sb to the Ga atom. The formation of 5 illustrates the high-synthetic potential of 1 for the formation of new compounds with unusual electronic structures.

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Section: Resultsmentioning

confidence: 71%

“…Thermolysis at 120 °C for 30 h yielded LGa and distibene [L(Cl)Ga] 2 Sb 2 , which further underwent LGaCl 2 and LGa elimination and finally formed [L(Cl)Ga] 2 Sb 4 (Supplementary Figs. 24–26) 33 . 1 H and 13 C NMR spectra of 5 show the expected resonances of the organic substituents (Supplementary Figs.…”

Section: Resultsmentioning

confidence: 99%

From stable Sb- and Bi-centered radicals to a compound with a Ga=Sb double bond

et al. 2018

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“…LGa with different main group metal compounds including InEt 3 , [15] BiEt 3 , [16] Sb(NMe 2 ) 3 , [17] E 2 Et 4 (E = Sb, Bi) [18] as well as TeEt 2 and Te 2 Et 2 , [19] respectively, in detail. We herein expanded our investigations on reactions of LGa with different group 13 Lewis acids M(C 6 F 5 ) 3 (M = B, Al, Ga) and also report on their potential use for small molecule activation reactions such as benzaldehyde.…”

Section: Introductionmentioning

confidence: 99%

Lewis acid–base adducts of group 13 elements: synthesis, structure and reactivity toward benzaldehyde

et al. 2016

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Lewis acid-base adducts [LGa-M(C6F5)3] (M = B 1, Al 2, Ga 3) were prepared by the reaction of gallanediyl LGa {L = HC[C(Me)N(2,6-i-Pr2C6H3)]2} with the Lewis acids M(C6F5)3 (M = B, Al, Ga). Benzaldehyde reacts with [LGa-M(C6F5)3] (M = B 1, Al 2) at room temperature with the insertion and formation of [LGa(C6F5){CH(Ph)(OB(C6F5)2)}] (4) and the zwitterionic species [LGa(C6F5){CH(Ph)(OAl(C6F5)2)}] (5), respectively, which was found to decompose at 80 °C with the formation of {(C6F5)2Al(OCH2Ph)}2 (6). Any attempts to isolate the insertion complex of [LGa-Ga(C6F5)3] with benzaldehyde failed and only {(C6F5)2Ga(OCH2Ph)}2 (7) was isolated at elevated temperatures. 2-5 and 7 were structurally characterized by heteronuclear NMR spectroscopy and single crystal X-ray diffraction.

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“…[91] Reduction of SnCl 2 by low-valent Ga I (ddp) (ddp = 2-{(2,6-diisopropylphenyl)amino}-4-{(2,6-diisopropylphenyl)i-mino}-2-pentene) enables the formation of [Sn 17 {GaCl-(ddp)} 4 ], al igand-stabilized, but empty counterpart of the endohedrally filled dimer [Co 2 @Sn 17 ] 5À discussed above. Afeature which was also found to be of use in the preparation of the heterometallic gallium and [93] and is commonly employed in the preparation of the later-on discussed Hume-Rothery type cluster compounds combining group 12 and 13 elements with d-block metals (section 4). Afeature which was also found to be of use in the preparation of the heterometallic gallium and [93] and is commonly employed in the preparation of the later-on discussed Hume-Rothery type cluster compounds combining group 12 and 13 elements with d-block metals (section 4).…”

Section: Low-valent and Other Molecular Precursorsmentioning

confidence: 99%

Intermetalloid Clusters: Molecules and Solids in a Dialogue

et al. 2018

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Atom-precise, ligand-stabilized metalloid clusters have emerged as outstanding model systems to study fundamental structure and bonding situations of compositionally related molecules and extended solid phases. However, this fascinating field of research is still largely restricted to homometallic and pseudo-heterometallic systems of closely related d-block metals. In this review, we will highlight our own and others' efforts to project the structural and compositional diversity of intermetallics with dissimilar d- and p-block metal combinations, particularly the Zintl and Hume-Rothery phases, onto the molecular level in order to bridge the still gaping chasm between heterometallic molecular coordination chemistry and solid-state intermetallics. Herein, fundamental synthetic approaches, as well as structural and electronic properties of thus accessible "molecular alloys" will be addressed, and placed against their exceptional position as intermediates on the way to nanomaterials.

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A Gallium‐Substituted Distibene and an Antimony‐Analogue Bicyclo[1.1.0]butane: Synthesis and Solid‐State Structures

Cited by 68 publications

References 125 publications

From stable Sb- and Bi-centered radicals to a compound with a Ga=Sb double bond

From stable Sb- and Bi-centered radicals to a compound with a Ga=Sb double bond

Lewis acid–base adducts of group 13 elements: synthesis, structure and reactivity toward benzaldehyde

Intermetalloid Clusters: Molecules and Solids in a Dialogue

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