Preparation and Molecular Structure of a Cyclopentyl-Substituted Cage Hexasilsesquioxane T6 (T = cyclopentyl-SiO1.5) Starting from the Corresponding Silanetriol

Kahr, Jürgen; Belaj, Ferdinand; Pietschnig, Rudolf

doi:10.3390/inorganics5040066

Cited by 8 publications

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“…In comparison to the free ligands, the ν as (N 3 ) vibrations generally experience a slight shift to higher wavenumbers while the ν s (N 3 ) modes are mostly unaffected by the lanthanide ion coordination. The 29 Si NMR resonances of the protonated POSS cages can be found with a ratio of (31), Er (32)) crystallize in the monoclinic space group P2 1 /n (Figure 6). On the one hand, these compounds exhibit two terminal, 6-foldcoordinated Ln 3+ cations (Ln1) where each is exclusively coordinated by a T 7 (O − ) 3 cage, by the two T 6 (OH) 2 (O − ) 2 Hydrogens and phenyl substituents are omitted for clarity.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Herein, we present a modified procedure for the preparation of L1 as well as the synthesis of three new 4- or 4′-azido functionalized phosphonate ester ligands L2 – L4 comprising different aromatic backbones. In combination with our expertise in POSS (polyhedral oligomeric silsesquioxane)-cage chemistry, − these ligands are then applied in R POSS-cage-supported (R = i Bu, Ph) Ln 3+ ion coordination to function as anchor groups for future immobilization of these complexes on (In/Ga)P semiconductor surfaces and subsequent evaluation of their potential as optically switchable isolated molecular quantum bits. In this context, an azido functionalization at the 4- or 4′-position of L1 – L4 is expected to be the most suitable to avoid steric congestion between a semiconductor surface and the rest of the POSS-cage-supported complexes.…”

Section: Introductionmentioning

confidence: 99%

“…Er 2 {T 7 (O) 3 }{T 6 (OH) 2 (O) 2 }(μ 3 -OH)(L2)] 2(32) Average values are given for compounds with more than one molecule in the asymmetric unit or for more than one ligand of the same kind attached to a lanthanide ion.…”

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Azido-Functionalized Aromatic Phosphonate Esters in ^RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

et al. 2021

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Within this work, a modified preparation of diethyl 4-azidobenzylphosphonate (L1) is presented and the family of 4-or 4′-azido-substituted aromatic phosphonate esters is increased by three new ligand platforms: diisopropyl 4-azidobenzylphosphonate (L2), diisopropyl ((4′-azido-[1,1′-biphenyl]-4-yl)methyl)phosphonate (L3), and diisopropyl 4-azido-2,3,5,6-tetrafluorobenzylphosphonate (L4), which exhibit an anomalous splitting of the N 3 stretching vibrations. Subsequent coordination to the in situ generated R POSS (polyhedral oligomeric silsesquioxane)-cage-supported lanthanide precursors [(Ln{ R POSS}) 2 (THF) m ] (P1−P6) (Ln = La, Nd, Dy, Er; R = iBu, Ph; m = 0, 1) yields complexes of the general formula [Ln{ R POSS}(L1−L4) n (S1) x (THF) m ] (1−30) (n = 2, 3; x = 0, 1; m = 0−2) retaining the azide unit for future semiconductor surface immobilization. Because the latter compounds are mostly oils or viscous waxes, preliminary solution-state structure elucidations via DOSY-ECC-MW estimations have been carried out which are in accordance with 1 H NMR integral ratios as well as solidstate structures, where available. Moreover, the optical properties of the Nd, Dy, and Er derivatives of complexes 1−30 are examined in the visible and NIR spectral regions, where applicable.

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confidence: 99%

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confidence: 99%

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Azido-Functionalized Aromatic Phosphonate Esters in ^RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

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“…The conversion of this disilene into the corresponding potassium disilenide and its reactivity towards various electrophiles are also described. Von Hänisch's group discusses the incorporation of a disilane unit into crown ether, leading the preparation of 1,2-disila [18]crown-6, as well as 1,2-disila-benzo [18]crown-6 [17]. The complexation ability with ammonium cations by these disilane-containing crown ethers is examined, and corresponding complexes are successfully isolated.…”

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confidence: 99%

“…The complexation ability with ammonium cations by these disilane-containing crown ethers is examined, and corresponding complexes are successfully isolated. Pietschnig and coworkers highlight the synthesis of cyclopentyl-substituted silanetriol and its condensation that leads to the isolation of corresponding disiloxanetetrol and also hexameric polyhedral silsesquioxane cage T 6 [18].…”

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Coordination Chemistry of Silicon

Inoue¹

2019

Inorganics

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It is with great pleasure to welcome readers to this Special Issue of Inorganics, devoted to "Coordination Chemistry of Silicon". Investigations into silicon compounds continue to afford a wealth of novel complexes, with unusual structures and brand-new reactivities. In fact, the ongoing quest for silicon complexes with novel properties has led to a large number of silicon compounds, that contain various types of ligands or substituents. Use of the divergent coordination behavior of silicon to construct sophisticated low-and hyper-valent silicon complexes makes it possible to change their electronic structures and properties. Therefore, progress of the coordination chemistry of silicon can be the key concept for the design and development of next generation silicon compound-based applications. This Special Issue is associated with the most recent advances in coordination chemistry of silicon with transition metals, as well as main group elements, including the stabilization of low-valent silicon species through the coordination of electron-donor ligands, such as N-heterocyclic carbenes (NHCs) and their derivatives [1,2]. This Special Issue is also dedicated to the development of novel synthetic methodologies, structural elucidations, bonding analyses, and possible applications in catalysis or chemical transformations, using related organosilicon compounds [3]. Besides, recent years have witnessed great research efforts in silicon-based polymer chemistry, as well as silicon surface chemistry, which have become increasingly important for unveiling the correlations between nanoscopic structural features and macroscopic material properties, including the coordination behavior at silicon.The 19 articles composing this Special Issue can be considered as a representative selection of the current research on this topic, reflecting the diversity of silicon chemistry and yield an impressive compilation.Intrinsic coordination behaviors of silanes towards transition metals are the subject of several articles in this issue. For example, Nakata et al. discuss the synthesis and structure of a hydrido platinum(II) complex with a dihydrosilyl ligand that bears a bulky 9-triptycyl group [4]. The ligand exchange reaction of this mononuclear (hydrido)(dihydrosilyl) complex with various phosphines has also been studied. Sunada and coworkers provide an elegant method for accessing planar tetrapalladium clusters starting from octa(isopropyl)cyclotetrasilane through the insertion of palladium atoms into the Si-Si bonds of the cyclotetrasilane [5]. While the ligand exchange reaction with NHCs yields the more coordinatively unsaturated cluster, reaction with a trimethylolpropane phosphite affords a planar tripalladium cluster. Wagler and coworkers demonstrate a striking coordination chemistry of (2-pyridyloxy)silanes with transition metals (Pd, Cu) [6]. The molecular structures of the complexes have been elucidated by crystallographic analysis, and further computational investigations provided an in-depth understanding of the interatomic ...

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Cagelike metallagermanates and metallagermoxanes: Synthesis, structures and functional properties

Levitsky

Bilyachenko

Shubina

2019

Coordination Chemistry Reviews

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Preparation and Molecular Structure of a Cyclopentyl-Substituted Cage Hexasilsesquioxane T6 (T = cyclopentyl-SiO1.5) Starting from the Corresponding Silanetriol

Cited by 8 publications

References 29 publications

Azido-Functionalized Aromatic Phosphonate Esters in ^RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

Azido-Functionalized Aromatic Phosphonate Esters in ^RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

Coordination Chemistry of Silicon

Cagelike metallagermanates and metallagermoxanes: Synthesis, structures and functional properties

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Preparation and Molecular Structure of a Cyclopentyl-Substituted Cage Hexasilsesquioxane T6 (T = cyclopentyl-SiO1.5) Starting from the Corresponding Silanetriol

Cited by 8 publications

References 29 publications

Azido-Functionalized Aromatic Phosphonate Esters in RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

Azido-Functionalized Aromatic Phosphonate Esters in RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

Coordination Chemistry of Silicon

Cagelike metallagermanates and metallagermoxanes: Synthesis, structures and functional properties

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Azido-Functionalized Aromatic Phosphonate Esters in ^RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination

Azido-Functionalized Aromatic Phosphonate Esters in ^RPOSS-Cage-Supported Lanthanide Ion (Ln = La, Nd, Dy, Er) Coordination