2,4,6-Tri-tert.butylphenyl-substituierte Silane

2,4,6-Tri-tert.butylphenyl Substituted Silanes 2,4,6-Tri-tert.butylphenyl lithium reacts with trimethoxysilane, triethoxysilane, and triphenoxysilane to give the dialkoxy- or diphenoxy-(2,4,6-tri-tert.butylphenyl)-silanes Ar? SiH(OR¹)₂ 3 ? 5 (Ar = 2,4,6-tri.tert.butylphenyl, R¹ = Me, Et, Ph). Interaction of methyl lithium or n-butyl lithium with 3 – 5 leads under partial or complete substitution of the OR¹-functions to the silanes Ar? SiH(OR¹)R² 7 – 11 and Ar? SiHR₂² 12 and 13 (R² = Me, Bu). Reaction of 3 with lithium tert.butul-amide gives tert.butylamino-methoxy-(2,4,6-tri-tert.butylphenyl)-silane 14 . 5 is reduced by LiAlH₄ to 2,4,6-tri-tert.butylphenyl-silane 6 . The reaction of 3 with antimony trifluoride results in formation of 2,4,6-tri-tert.butylphenyl trifluorosilane 2 . Attempts to replace the alkoxy or phenoxy groups in 3 – 5 by chlorine led under silion carbon bond cleavage to 1,3,5-tri-tert.butylbenzene.     

Preparation of Silica/Poly(tert‐butylmethacrylate) Core/Shell Nanocomposite Latex Particles

Nanocomposite latex particles, with a silica nanoparticle as core and crosslinked poly(tert‐butylmethacrylate) as shell, were prepared in this work. Silica nanoparticles were first synthesized by a sol‐gel process, and then modified by 3‐(trimethoxysilyl)propyl methacrylate (MPS) to graft C?C groups on their surfaces. The MPS‐modified silica nanoparticles were characterized by elemental analysis, FTIR, and ²⁹Si NMR and ¹³C‐NMR spectroscopy; the results showed that the C?C groups were successfully grafted on the surface of the silica nanoparticles and the grafted substance was mostly the oligomer formed by the hydrolysis and condensation reaction of MPS. Silica/poly(tert‐butylmethacrylate) core/shell nanocomposite latex particles were prepared via seed emulsion polymerization using the MPS‐modified silica nanoparticle as seed, tert‐butylmethacrylate as monomer and ethyleneglycol dimethacrylate as crosslinker. Their core/shell nanocomposite structure and chemical composition were characterized by means of TEM and FTIR, respectively, and the results indicated that silica/poly(tert‐butylmethacrylate) core/shell nanocomposite latex particles were obtained.     

Die Reaktion des tert.Butyl-lithiums mit Aluminiumtribromid; Molekülstrukturen von [HAl(CMe3)2]3 und [LiHAl(CMe3)3]2

Reaction of tert.Butyl-lithium with Aluminiumtribromide; Molecular Structures of [HAl(CMe₃)₂]₃ and [LiHAl(CMe₃)₃]₂ The reaction of tert.butyl-lithium with aluminiumtrihalide at low temperatures was reinvestigated. Four compounds were isolated: trimeric di(tert.butyl)alane(III) 1 , monomeric (solution in benzene)/dimeric (solid state) lithium-tri(tert.butyl)alanate(III) 2 , tri(tert.butyl)alane 3 and lithium-tetra(tert.butyl)alanate 4 . X-ray structure analyses gave a planar sixmembered Al? H heterocycle for 1 and a Li? H-bridged dimer showing intramolecular interactions of lithium with C? H σ-bonds for 2 .     

2,4,6-Tris(tert.butyl)phenyl-substituierte Phosphine

2,4,6-Tris(tert.butyl)phenyl Substituted Phosphines Tris(tert.butyl)phenyl-lithium reacts with PCl₃ to give 2,4,6-tris(tert.butyl)phenyldihalogenophosphine which is reduced by LiAlH₄ yielding 2,4,6-tris(tert.butyl)phenylphosphine. The same reaction by using (CH₃)₃Si? CH₂? PCl₂ leads to 2,4,6-tris(tert.butyl)phenyl-trimethylsilylmethylhalogenophosphine. Thermal treatment of this compound results under elimination of HCl and (CH₃)₃SiCl in the formation of . The nmr data of the compounds synthesized are discussed.     

A Dodecalanthanide Wheel Supported by p‐tert‐Butylsulfonylcalix[4]arene

A dodecaholmium wheel of [Ho₁₂(L)₆(mal)₄(AcO)₄(H₂O)₁₄] ( 1 ; mal=malonate) was synthesized by using p‐tert‐butylsulfonylcalix[4]arene (H₄L) as a cluster‐forming ligand. The wheel consists of three fragments of mononuclear A^3? ([Ho(L)(mal)(H₂O)]^3?), trinuclear B^3? ([Ho(H₂O)₂(mal)(Ho(L)(AcO))₂]^3?), and C³⁺ ([Ho(H₂O)₂]³⁺), and an alternate arrangement of these fragments (A^3?? C³⁺? B^3?? C³⁺? A^3?? C³⁺? B^3?? C³⁺? ) results in a wheel structure. The longest and shortest diameters of the core were estimated to be 17.7562(16) and 13.6810(13) Å, respectively, and the saddle‐shaped molecule possesses a pocketlike cavity inside.     

Highly Selective and Catalytic Oxygenations of C−H and C=C Bonds by a Mononuclear Nonheme High‐Spin Iron(III)‐Alkylperoxo Species

The reactivity of a mononuclear high‐spin iron(III)‐alkylperoxo intermediate [Fe^III(t‐BuL^Urea)(OOCm)(OH₂)]²⁺( 2 ), generated from [Fe^II(t‐BuL^Urea)(H₂O)(OTf)](OTf) ( 1 ) [t‐BuL^Urea=1,1′‐(((pyridin‐2‐ylmethyl)azanediyl)bis(ethane‐2,1‐diyl))bis(3‐(tert‐butyl)urea), OTf=trifluoromethanesulfonate] with cumyl hydroperoxide (CmOOH), toward the C?H and C=C bonds of hydrocarbons is reported. 2 oxygenates the strong C?H bonds of aliphatic substrates with high chemo‐ and stereoselectivity in the presence of 2,6‐lutidine. While 2 itself is a sluggish oxidant, 2,6‐lutidine assists the heterolytic O?O bond cleavage of the metal‐bound alkylperoxo, giving rise to a reactive metal‐based oxidant. The roles of the urea groups on the supporting ligand, and of the base, in directing the selective and catalytic oxygenation of hydrocarbon substrates by 2 are discussed.     

Stepwise Formation of a 1,3‐Butadiene Analogue of Mixed Heavier Group 15 Elements

The reaction of the phosphinidene complex [Cp*P{W(CO)₅}₂] ( 1 a ) with di‐tert‐butylcarboimidophosphene leads to the P? C cage compound 6 and the Lewis acid–base adduct [Cp*P{W(CO)₅}₂(CNtBu)] ( 2 a ). In contrast, the arsinidene complex shows a different reactivity. At low temperatures, the arsaphosphene complex [{W(CO)₅}{η²‐(Cp*)As?P(tBu)}{W(CO)₅}] ( 3 ) is formed. At these temperatures, 3 reacts further with a second equivalent of carboimidophosphene to form [{W(CO)₅}{η²‐{(Cp*)(tBu)P}As?P(tBu)}{W(CO)₅}] ( 5 ), probably by the insertion of a phosphinidene unit (tBuP) into an As? C bond. In contrast, at room temperature 3 reacts further by a radical‐type reaction to form [{(tBu)P?As? As?P(tBu)}{W(CO)₅}₄] ( 4 ). Compound 4 is the first example of a neutral, 1,3‐butadiene analogue containing only mixed heavier Group 15 elements. It consists of two P?As double bonds connected by arsenic atoms.     

Kinetics and mechanism of oxidative deoximation of benzaldoxime by diperiodatocuprate(III) intert.-butanol — Water medium

Summary The kinetics of oxidation of benzaldoxime by diperiodatocuprate(III) (DPC) was studied spectrocolorimetrically at 414 nm intert.-butanol — water medium. The order in [DPC] and that in [benzaldoxime] was unity. The rate increased with increasing [OH^–] and decreasing [IO ₄ ^– ]. A suitable mechanism is proposed based on the kinetic data.

---

Kinetik und Mechanismus der oxidativen Deoximierung von Benzaldoxim mit Diperjodatocuprat(III) intert.-Butanol/Wasser

Zusammenfassung Es wurde die Kinetik der Oxidation von Benzaldoxim mit Diperjodatocuprat(III) (DPC) intert.-Butanol/Wasser colorimetrisch bei 414 nm untersucht. Die Reaktionsordnung bezüglich [DPC] und [Benzaldoxim] war gleich 1. Die Reaktionsgeschwindigkeit erhöhte sich mit Zunahme der Konzentration von [OH^–] und Verminderung von [IO ₄ ^– ]. Basierend auf den kinetischen Daten wird ein passender Mechanismus vorgeschlagen.

     

Synthesis and Characterization of Methylzinc Tri(tert‐butyl)silylphosphanide as well as Related Sodium and Potassium Phosphanylzincates

The reaction of dimethylzinc and tri(tert‐butyl)silylphosphane in toluene yielded dimeric methylzinc tri(tert‐butyl)silylphosphanide ( 1 ) which crystallized tetrameric. Compound 1 was deprotonated with sodium in DME and the solvent‐separated dimeric ion pair [(dme)₃Na]⁺ [(dme)Na(MeZn)₂(μ‐PSitBu₃)₂]^? ( 2 ) was isolated. The reaction of 1 in THF with two equivalents of potassium and one equivalent of tri(tert‐butyl)silylphosphane gave dimeric [{tBu₃Si(H)P}{(thf)₂K}₂(MeZn)(PSitBu₃)]₂ ( 3 ). Both of these phosphanylzincates contain Zn₂P₂ cycles with Zn‐P bond lengths of approximately 237 pm, whereas in 1 larger Zn‐P bond lengths of 248.5 pm were found due to the larger coordination numbers of the phosphorus and zinc atoms.     

Experimental and theoretical investigations of the antioxidant activity of 2,2′‐methylenebis(4,6‐dialkylphenol) compounds

The antioxidant activity of two primary antioxidants, 2,2′‐methylenebis(4‐methyl‐6‐tert ‐butylphenol) (MMBPH2) and 2,2′‐methylenebis(4,6‐di‐tert ‐butylphenol) (MDBPH2), has been studied using the 1,1‐diphenyl‐2‐picrylhydrazyl (DPPH) method. The synthesized compounds have been successfully characterized systematically using elemental analyses, infrared, ¹H NMR and ¹³C NMR spectra and GC–MS. Importantly, it has been found that the compound MMBPH2 in particular is more active in DPPH radical scavenging. In addition, density functional theory calculations (B3LYP) have been used to predict the antioxidant activity and predict structural geometries of the compounds in the gas phase.     

Trapping and Reactivity of a Molecular Aluminium Oxide Ion

Aluminium oxides constitute an important class of inorganic compound that are widely exploited in the chemical industry as catalysts and catalyst supports. Due to the tendency for such systems to aggregate via Al‐O‐Al bridges, the synthesis of well‐defined, soluble, molecular models for these materials is challenging. Here we show that reactions of the potassium aluminyl complex K₂[( NON )Al]₂ ( NON =4,5‐bis(2,6‐diiso‐propylanilido)‐2,7‐di‐tert‐butyl‐9,9‐dimethylxanthene) with CO₂, PhNCO and N₂O all proceed via a common aluminium oxide intermediate. This highly reactive species can be trapped by coordination of a THF molecule as the anionic oxide complex [( NON )AlO(THF)]^?, which features discrete Al?O bonds and dimerizes in the solid state via weak O???K interactions. This species reacts with a range of small molecules including N₂O (to give a hyponitrite ([N₂O₂]^2?) complex) and H₂, the latter offering an unequivocal example of heterolytic E?H bond cleavage across a main group M?O bond.     

The carboxyl derivatives of 6,8-di-(tert.-butyl)phenoxazine: Synthesis,oxidation reactions and fluorescence

New carboxyl-containing o-aminophenols and phenoxazines were synthesized by condensation of 3,5-di-(tert.-butyl)-quinone with p-aminobenzoic and anthranilic acids. Oxidative transformations of the o-aminophenols and intermediate o-iminoquinones occur with the formation of the ESR detected phenoxazinyl radicals, which furthermore transform to phenoxazines or the dimeric products emerged through the radical attack at the C1 carbon of a formed phenoxazine. Molecular structure of the dimer obtained by oxidation of methyl ester of 4-[3,5-di-(tert.-butyl)-1-(2′-hydroxyphenyl)amino]benzoic acid was X-ray determined. Reaction of 4-[3,5-di-(tert.-butyl)-1-(2′-hydroxyphenyl)amino]benzoic acid with thionyl chloride gives rise to the formation of a derivative of 2-oxido-3H-benzo[d,j][1,2,3]oxathiazol system, the structure of which was established using X-ray crystallography. Solutions of methyl-6,8-di-(tert.-butyl)-10H-phenoxazine-3-carboxylate solvents display intense fluorescence covering a broad spectral region in the range of 400–600?nm.     

Beiträge zur Chemie des Hydrazins und seiner Derivate. 52. Kristall- und Molekülstrukturen der tert.-Butyloxycarbonylderivate von Cyclotetraschwefeldihydrazid und Cyclohexaschwefelhydrazid

Contributions to the Chemistry of Hydrazine and its Derivatives. 52. Crystal and Molecular Structures of the tert.-Butyloxycarbonyl Derivatives of Cyclotetrasulfurdihydrazide and Cyclohexasulfurhydrazide The structures of the tert.-butyloxycarbonyl derivatives of cyclotetrasulfurdihydrazide and cyclohexasulfurhydrazide were determined by X-ray analyses. Both sulfur(II)-nitrogen rings exist in crown conformation and contain only sp²-hybridized nitrogen atoms. Bond lengths, bond angles, and dihedral angles are discussed.     

Tetrakis(5‐tert‐butylpyrazole‐1κN2)tetrachloro‐1κCl,2κ3Cl‐μ‐oxo‐1:2κ2O‐diiron(III)

The title compound, [Fe₂Cl₄O(C₇H₁₂N₂)₄], contains vertex‐sharing distorted tetrahedral [FeOCl₃]^? and octahedral [FeOCl(Hpz^tBu)₄]⁺ moieties (Hpz^tBu is 5‐tert‐­butyl­pyrazole), linked by a bent oxo bridging ligand. The two Fe^III centres are also bridged by intramolecular hydrogen bonds between the pyrazole N—H groups and the O^2? and Cl^? ligands.     

Synthesis of a Tweezer—like Bis（Phenylthiapropoxy）calix[4]—arene as a Cation／π Enhanced Sensor for Ion—Selective Electrodes

Two novel 25,27-dihydroxy-26,28-bis(3-phenylthiapropxy)-calix[4]arene(3) and 25,27-dihydroxy-26,28-bis(3-phenylthiapropoxy)-5,11,17,23-tetra-tert-butylcalix[4] arene (4) were synthesized for the evaluation of their ion-selectivity in ion-selective electrodes(ISEs).ISEs based on 3 and 4 as neutral ionophores were prepared,and their selectivity coefficients for Ag^ (lg KAg,M^pot)were investigated against other alkali metal,alkaline-earth metal,aluminum,thallium(Ⅰ）,Lead and some transition metal ions using the separate solution method (SSM).These ISEs showed excellent Ag^ seletivity over most of the interfering cations examined,except for Hg^2 and Fe^2 having relative smaller interference(lg KAg,M^pot≤-2.1).     

Oxidation of Bromide by Tert‐Butyl Hypochlorite

The kinetics of the oxidation reaction of bromide by tert‐butyl hypochlorite (^tBuOCl) was studied at 25°C, ionic strength 0.5 M, and under isolation conditions. A stopped‐flow spectrophotometer was employed for monitoring the reactions. Kinetic studies show that the reaction is first order with respect to [Br^?] and [^tBuOCl]. Linear dependences of the proton concentration, in perchloric acid medium, and the buffer solution concentration were found on the rate constant. The activation parameters were calculated using the Arrhenius and Eyring equations from the kinetic studies performed to analyze the influence of temperature on the rate constant. The results are consistent with a reaction mechanism of general acid catalysis. The catalytic constants were obtained for the oxidation of bromide by tert‐butyl hypochlorite. The slope obtained for the Brönsted relationship was 0.36.     

Substitutionsprodukte des Cyclopentadiens, 5. Mitt.: 1- und 2-tert.-Butylcyclopentadien

Zusammenfassung Ein vorwiegend als 1-Isomeres reagierendes tert.-Butylcyclopentadienpräparat läßt sich durch Umsetzung von tert.-Butylchlorid mit Cyclopentadien-Magnesiumhalogenid bei 0° und Aufarbeitung bei Temperaturen unter 25° gewinnen. Das früher beschriebene³ tert.-Butylcyclopentadien ist ein Isomerengemisch, in dem 1-und 2-Substitutionsprodukt nachgewiesen werden konnten.Auf Wunsch der Autoren erscheint diese Abhandlung erst im Oktoberheft 1960.4. Mitt., Mh. Chem.90, 573 (1959).     

Synthese,spektroskopische Charakterisierung und Molekülstrukturen ausgewählter Lewis‐Basen‐Addukte der Alkalimetall‐tri(tert‐butyl)silylphosphanide

Synthesis, Spectroscopic Characterization, and Molecular Structures of Selected Lewis‐Base Adducts of the Alkali Metal Tri(tert‐butyl)silylphosphanides The metalation of tri(tert‐butyl)silylphosphane with butyllithium and the bis(trimethylsilyl)amides of sodium, potassium, and rubidium yields quantitatively the corresponding alkali metal tri(tert‐butyl)silylphosphanides, which crystallize after addition of appropriate Lewis‐bases as dimeric (DME)LiP(H)SitBu₃ ( 1 ), chain‐like (DME)NaP(H)SitBu₃ ( 2 ), monomeric ([18]Krone‐6)KP(H)SitBu₃ ( 3 ), and dimeric (TMEDA)_1.5RbP(H)SitBu₃ ( 4 ). The reaction of H₂PSitBu₃ with cesium bis(trimethylsilyl)amide at room temperature gives monocyclic and tetrameric cesium tri(tert‐butyl)silylphosphanide ( 5 ) with two additional coordinated CsN(SiMe₃)₂ molecules. At 80 °C this complex reacts with excess of phosphane to the tetrameric toluene adduct (η⁶‐Toluol)CsP(H)SitBu₃ ( 6 ) which contains a central Cs₄P₄‐heterocubane fragment. The constitution of these compounds was verified by X‐ray structure determinations.     

Chemie polyfunktioneller Moleküle. 119 [1] Tetracarbonyl-dicobalt-tetrahedran-Komplexe mit den Liganden Bis(diphenyl-phosphanyl)amin, 2-Butin-1,4-diol und tert-Butylphosphaacetylen — Kristallstrukturanalyse des Phosphaalkin-Derivats

Chemistry of Polyfunctional Molecules. 119 [1]. Tetracarbonyl-dicobalt-tetrahedrane Complexes with the Ligands Bis(diphenylphosphanyl)-amine, 2-Butin-1,4-diol, and tert.-Butylphosphaacetylene — Crystal Structure of the Phosphaalkyne Derivative Co₂(μ-CO)₂(CO)₄(μ-Ph₂P? NH? PPh₂—P,P′) · 1/2C₆H₅CH₃ ( 4 · 1/2C₆H₅CH₃) reacts with 2-butine-1,4-diol, HOCH₂? C?C? CH₂OH ( 5 ), to the dark-red tetrahedrane complex Co₂(CO)₄(μ-η²,η²-HOCH₂? C?C? CH₂OH? C², C³) · (μ-Ph₂P? NH? PPh₂? P,P′) · THF (6 · THF). With t-butyl-phosphaacetylene, tBu? C?P ( 7 ), 4 · THF forms Co₂(CO)₄(μ-η²,η²-tBu? C?P)(μ-Ph₂P? NH? PPh₂? P,P′) ( 8 ), which also belongs to the tetrahydrane type. The compounds were characterized by their mass, IR, ³¹P{¹H} NMR, ¹³C{¹H} NMR, and¹H NMR spectra. Crystals suitable for X-ray structure analyses have been obtained for 8 from dioxane. The dark red blocks crystallize in the monoclinic P2₁/c space group with the lattice constants a = 1404,1(5), b = 1330,0(7), c = 2578,8(10)pm; β = 90,82(3)°.     

A stable silagermene (tBu3Si)2Si=Ge(mes)2 (mes = 2,4,6‐trimethylphenyl): Synthesis,X‐ray crystal structure,and thermal isomerization

A stable silagermene, 1,1‐bis(tri‐tert‐butylsilyl)‐2,2‐bis(2,4,6‐trimethylphenyl)silagermene, was synthesized by the reaction of dilithiosilane (^tBu₃Si)₂SiLi₂ with dichlorodimesitylgermane. Its structure was determined by spectroscopic data and X‐ray crystallography, which showed the SiGe length to be 2.2769(8) Å. The silagermene underwent isomerization at 100ˆC to form the corresponding symmetrically substituted isomer (E)‐1,2‐bis(tri‐tert‐butylsilyl)‐1,2‐bis(2,4,6‐trimethylphenyl)silagermene. © 2008 Wiley Periodicals, Inc. Heteroatom Chem 19:649–653, 2008; Published online in Wiley InterScience ( www.interscience.wiley.com ). DOI 10.1002/hc.20503