Pyridine adduct with

This fact is consistent with a bimolecular reaction between the two pyridine adducts, with a transition state as shown in (VII), containing two five-coordinate aluminum atoms. 

Figure 1. A comparison of (a) the molecule of hexakis( -hydroxylphenyloxy)benzene (2) in its pyridine adduct with (b) the hydrogen-bonded hexameric unit of g-hydroquinone.

Sulfur trioxide reactivity can also be moderated through the use of SO adducts. The reactivity of such complexes is inversely proportional to their stabihty, and consequentiy they can be selected for a wide variety of conditions. Whereas moderating SO reactivity by adducting agents is generally beneficial, the agents add cost and may contribute to odor and possible toxicity problems in derived products. CeUulosic material has been sulfated with SO.—trimethyl amine adduct in aqueous media at 0 to 5°C (16). Sulfur trioxide—triethyl phosphate has been used to sulfonate alkenes to the corresponding alkene sulfonate (17). Sulfur trioxide—pyridine adduct sulfates oleyl alcohol with no attack of the double bond (18). 

Complex Formation. B-Ttichlorobora2iQe was reported to readily form crystalline adducts of uncertain stmcture with pyridine (131). The Lewis acids aluminum tribromide or gallium trichloride form 1 1 adducts with hexamethylbota2iQe (eq. 36) ia which the metal atom coordinates with a nitrogen with loss of planarity of the ring (132,133). 

SF4 is unusual in apparently acting both as an electron-pair acceptor and an electron-pair donor (amphoteric Lewis acid-base). Thus pyridine forms a stable 1 1 adduct C5H5NSF4 which presumably has a pseudooctahedral (square-pyramidal) geometry. Likewise CsF (at 125°) and Me4NF (at —20°) form CsSFs and [NMe4]+[SFs] (Fig. 15.21a). By contrast, SF4 behaves as a donor to form 1 1 adducts with many Lewis acids the stability decreases in the sequence SbFs > AsFs > IrFs > BF3 > PF5 > ASF3. In view of the discussion on... 

The bicyclic nature of the labile adduct (79) from 3-methyl-pyridine was established by Acheson and Taylor who found that hydrogenation, yielding (80), followed by oxidation gave pyridine-3,4,5-tricarboxylic acid. This conclusion is consistent with Diels and Alder s observations that acid hydrolysis of the labile pyridine adduct gave pyridine and some crotonaldehyde, whereas alkaline hy-... 

The major product of this reaction is the yellow, labile, 1 2 molar adduct (134) corresponding to the pyridine series, along with a small amount of a colorless compound (139) which is discussed later and some phenanthridine oxalate. The labile adduct is converted to the stable isomer (135) on heating in quinoline or pyridine. Oxidation of both these adducts with potassium permanganate in acetone gives phenanthridone as the major product. In the case of the labile adduct. 

The 14e compound MTO readily forms coordination complexes of the type MTO-L and MTO-L2 with anionic and uncharged Lewis bases [96], These yellow adducts are typically five- or six-coordinate complexes, and the Re-L system is highly labile. Apart from their fast hydrolysis in wet solvents, MTO-L adducts are much less thermally stable then MTO itself. The pyridine adduct of MTO, for instance, decomposes even at room temperature. In solution, methyltrioxorhenium displays high stability in acidic aqueous media, although its decomposition is strongly accelerated at increased hydroxide concentrations [97, 98], Thus, under basic aqueous conditions MTO decomposes as shown in Equation (4). 

Titanium imido complexes supported by amidinate ligands form an interesting and well-investigated class of early transition metal amidinato complexes. Metathetical reactions between the readily accessible titanium imide precursors Ti( = NR)Cl2(py)3 with lithium amidinates according to Scheme 84 afforded either terminal or bridging imido complexes depending on the steiic bulk of the amidinate anion. In solution, the mononuclear bis(pyridine) adducts exist in temperature-dependent, dynamic equilibrium with their mono(pyiidine) homologs and free pyridine. 

Closely related pyridine adducts were prepared as shown in Scheme 126 by treatment of the corresponding chloro precursor with lithium amidinates. 

The majority of the work on xanthates of divalent nickel has, in recent years, been centered on the formation of base adducts with [Ni(Rxant)2]. Carlin and Siegel (348) and Daktenieks and Graddon (349) reported the formation of paramagnetic [Ni(Etxant)2B2] or [Ni(Etaxant)2B], where B = pyridine, 4-methylpyridine, bipyridyl, or... 

The inertness of H3SiMn(CO)j contrasts with the reactivity of its pyridine adduct H3SiMn(CO)j-ZCjHjN, which was decomposed quantitatively below —100° C [Eq. (67)] (11), (but see Section II,C,4). 

With its empty 3 d orbitals, SF4 also acts as a Lewis acid. This molecule forms adducts with pyridine and with fluoride ion. Each adduct has square pyramidal geometry, with a lone pair of electrons completing an octahedral... 

The degradation of tetrachloromethane by a strain of Pseudomonas sp. presents a number of exceptional features. Although was a major product from the metabolism of CCI4, a substantial part of the label was retained in nonvolatile water-soluble residues (Lewis and Crawford 1995). The nature of these was revealed by the isolation of adducts with cysteine and A,A -dimethylethylenediamine, when the intermediates that are formally equivalent to COClj and CSClj were trapped—presumably formed by reaction of the substrate with water and a thiol, respectively. Further examination of this strain classified as Pseudomonas stutzeri strain KC has illuminated novel details of the mechanism. The metabolite pyridine-2,6-dithiocarboxylic acid (Lee et al. 1999) plays a key role in the degradation. Its copper complex produces trichloromethyl and thiyl radicals, and thence the formation of CO2, CS2, and COS (Figure 7.64) (Lewis et al. 2001). 

As in the case of 2-substituted pyridine adducts, activation of an aromatic C—H bond is observed when the adducts of 6-thbipy and of 6-Bnbipy are heated under reflux in aqueous media. A cyclic dimer (1) with bridging N,C ligands is obtained in the first case [24], while cyclometallated derivatives [Au(N, N,C)C1] (2) are formed in... 

Hexfluorophosphate salts behave similarly.108 The diazonium tetrafluoroborates can be prepared either by precipitation from an aqueous solution by fluoroboric acid109 or by anhydrous diazotization in ether, THF, or acetonitrile using r-butyl nitrite and boron trifluoride.110 Somewhat milder reaction conditions can be achieved by reaction of aryl diazo sulfide adducts with pyridine-HF in the presence of AgF or AgNQ3. 

The cyclotetrasiloxane l,l,5,5-tetraphenyl-3,3,7,7-tetrahydroxycy-clotetrasiloxane forms a stable complex with two pyridine molecules trans to each other across the siloxane ring (316). The adduct may be prepared by the addition of an excess of pyridine to the free silanol the isomeric silanol [Ph(OH)SiO]4 does not form an adduct with pyridine (317). As well as hydrogen-bonding to the pyridine molecules, each of the two crystallographically independent molecules in the unit cell hydrogen-bonds to others of the same type to form two independent infinite chains (Fig. 24). Branching to form sheets by joining the chains, as in [But(0H)2Si]20, is partially blocked by the interactions with the... 

The displacement of one base coordinated to a stannylene SnX2 by another base can easily be achieved if the entering molecule is more basic than the leaving one. If an ether solution of 1 is allowed to react with pyridine, the weak ether adduct is converted to a pyridine adduct at —30 °C 112,134) ... 

Complex (77) has been obtained by electrolysis of the respective Ni11 species (i 1/2= —0.78 V vs. Cp2Fe/Cp2Fe+ in DMF) and represents the first Ni111 complex with aliphatic thiolato donors that could be characterized crystallographically.300 The overall square planar structure is retained, but the Ni—N and Ni—S distances shorten by 0.023 A and 0.057 A, respectively, upon oxidation. While (77) is EPR-silent, its pyridine adduct shows an axial spectrum (g = 2.313, 2.281, 2.000) with N-hyperfine coupling of the z-component, indicative of a (r )1 ground state. 

Heterocyclic nitrogen donors and their adducts with zinc chloride have been studied.623,624 A large number of other ligand systems have also been characterized, for example, zinc halide adducts of 2,2-dimethylpropane-1,3-diamine and hexamethylphosphoramide have been studied.625,626 The formation of mixed ligand complexes with chloride and substituted pyridines has been studied.627 The zinc tris(pyridyl) chloride anion has also been structurally characterized.628 Manganese(II) ions have been used to probe the stereochemistry in reactions of zinc halides with pyrazine.629... 

Since the nitrogen in pyridine is electron attracting it seemed reasonable to predict that the trihalopyridynes would also show the increased electrophilic character necessary to form adducts with aromatic hydrocarbons under similar conditions to those employed with the tetra-halogeno-benzynes. The availability of pentachloropyridine suggested to us and others that the reaction with w-butyl-lithium should lead to the formation of tetrachloro-4-pyridyl-lithium 82 84>. This has been achieved and adducts obtained, although this system is complicated by the ease with which pentachloropyridine undergoes nucleophilic substitution by tetrachloro-4-pyridyl lithium. Adducts of the type (45) have been isolated in modest yield both in the trichloro- and tribromo- 58) series. 

A well dried sample of this complex exploded violently when pushed through a funnel with a steel spatula. The pyridine adduct, which was being prepared, is claimed to be a useful, safe, oxidant, replacing the hexamethylphosphoramide complex of M0O5 (ibid.). 

Hydroboration-isomerization of 38 and 39 with BH3-THF in THF solution gives rise to THF-3-methyl-l-boraadamantane 40, which was further transformed into the air-stable adducts with pyridine 41a and 1-amino-adamantane 41b (Scheme 10) <2005MI1, 2005MI2>. 

The THF adduct 70 (mp 147 °C) and pyridine adduct 71 (mp 178°C) of bis-l-boraadamantane with one CH2 bridge were synthesized by hydroboration-cyclization of the bis-bicycle 72, available from hepta-l,6-diyne (Scheme 28) . 

Titanium(IV) iodide is extremely hygroscopic. It dissolves in water with decomposition, and it fumes in air owing to hydrolysis. It forms 2 1 adducts with ammonia,7 pyridine,33 and ethyl acetate.34 With excess ammonia it undergoes ammo-nolysis to give ammonobasic titanium(IV) iodides.7 Analogous aminolysis reactions occur when titanium(IV) iodide is treated with an excess of primary or secondary amine.36 Titanium(IV) iodide is sparingly soluble in petroleum ether, moderately soluble in benzene, and even more soluble in chlorinated hydrocarbons and carbon disulfide. At elevated temperatures it... 

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