Crystallographic evidence for intermolecular hydrogen bonding between aryl groups and OH groups in silanols

In crystals of the silanols (Me₃Si)₃CSiPh(X)OH (X  I or OMe) there is intermolecular π ⋯ HO bonding between a phenyl group in one molecule and an OH group in another, and there are probably intramolecular π ⋯ HO interactions in two silanols previously reported to show no hydrogen bonding. It is suggested that similar interactions should exist for OH groups attached to other metals or metalloids.     

Synthesis of Functionalized p-Phenylene Oxide Oligomers

Oligomers of p-phenylene oxides have been synthesized by coupling of substituted phenols and aryl bromides in the presence of cuprous chloride. The chain length varies from 2 to 5 phenyl rings functionalized at one end by an OH and OMe group and at the other end by an OH, OMe or NO₂ functions. The oligomers could be used in material science and as building blocks in supramolecular chemistry. Methods for chemoselective demethylation of methoxy groups were developed.     

Preparation and evaluation of a chiral stationary phase covalently bound with a chiral pseudo-18-crown-6 ether having a phenolic hydroxy group for enantiomer separation of amino compounds

In order to develop a chiral stationary phase (CSP), which has even higher separation ability than the corresponding commercially available crown ether based CSP (OA-8000 having a pseudo-18-crown-6 ether with an OMe group as a selector), chemically bonded type CSP having a phenolic OH group on a crown ring was developed. Normal mobile phases with or without acid additive can be used with this OH type CSP in contrast to the conventional OMe type CSP which has a neutral chiral selector. Enantiomers of 25 out of 27 amino compounds, including 20 amino acids, 5 amino alcohols, and 2 lipophilic amines, were efficiently separated on a column with this CSP. Nine amino compounds out of 27 were separated with better separation factors than the corresponding OMe type CSP. It is noteworthy that the chromatography on this CSP exhibited excellent enantiomer-separations for amines and amino alcohols when triethyl amine was used as an additive in the mobile phase. Comparison of enantiomer separation ability on this OH type of CSP and on the OMe type of CSP and correlation between the enantioselectivity in chiral chromatography and that of the corresponding model compounds in solution imply that the chiral separation arose from chiral recognition in host guest interactions.     

A Solvent Switch for the Stabilization of Multiple Hemiacetals on an Inorganic Platform: Role of Supramolecular Interactions

Reaction of Zn(OAc)₂ ? 2 H₂O with 2,6‐diisopropylphenyl phosphate (dippH₂) in the presence of pyridine‐4‐carboxaldehyde (Py‐4‐CHO) in methanol resulted in the isolation of a tetrameric zinc phosphate cluster [Zn(dipp)(Py‐4‐CH(OH)(OMe))]₄ ? 4 MeOH ( 1 ) with four hemiacetal moieties stabilized on the double‐4‐ring inorganic cubane cluster. The change of solvent from methanol to acetonitrile leads to the formation of [Zn(dipp)(Py‐4‐CHO)]₄ ( 2 ), in which the coordinated Py‐4‐CHO retains its aldehydic form. Dissolution of 1 in CD₃CN readily converts it to the aldehydic form and yields 2 . Similarly 2 , which exists in the aldehyde form in CD₃CN, readily converts to the hemiacetal form in CD₃OD/CH₃OH. Compound 1 is an unprecedented example in which four hemiacetals have been stabilized on a single molecule in the solid state retaining its stability in solution as revealed by its ¹H NMR spectrum in CD₃OD. The solution stability of 1 and 2 has further been confirmed by ESI‐MS studies. To generalize the stabilization of multiple hemiacetals on a single double‐four‐ring platform, pyridine‐2‐carboxaldehyde (Py‐2‐CHO) was used as the auxiliary ligand in the reaction between zinc acetate and dippH₂, leading to isolation of [Zn(dipp)(Py‐2‐CH(OH)(OMe))]₄ ( 3 ). Understandably, recrystallization of 3 from acetonitrile yields the parent aldehydic form, [Zn(dipp)(Py‐2‐CHO)]₄ ( 4 ). Single‐crystal X‐ray diffraction studies reveal that supramolecular bonding, aided by hydrogen‐bonding interactions involving the hemiacetal functionalities (C?OH, C?OMe, and C?H), are responsible for the observed stabilization. The hemiacetal/aldehyde groups in 1 and 2 readily react with p‐toluidine, 2,6‐dimethylaniline, and 4‐bromoaniline to yield the corresponding tetra‐Schiff base ligands, [Zn(dipp)(L)]₄ (L=4‐methyl‐N‐(pyridin‐4‐ylmethylidene)aniline ( 5 ), 2,6‐dimethyl‐N‐(pyridin‐4‐ylmethylene)‐aniline ( 6 ), and 4‐bromo‐N‐(pyridin‐4‐ylmethylene)aniline ( 7 )). Isolation of 5 – 7 opens up further possibilities of using 1 and 2 as new supramolecular synthons and ligands.     

Mono- and bis-alkoxides of tris(3,5-dimethylpyrazolyl)borato molybdenum and tungsten nitrosyls

The complexes [ML^*(NO)Cl(OR)] {L^* = HB(3,5-Me₂C₃HN₂)₃; M= Mo, R = CH₂CH₂X, X = Cl, OMe or OEt; (CH₂)_nOH, n = 2, 5, 6; M = W, R = CH₂CH₂X, X = Cl, OMe or OEt; (CH₂)_nOH, n = 2–6; CH₂(CF₂)₃CH₂OH; CHMeCH₂CMe₂OH} and [ML^*(NO)(OR)₂] {M = Mo, R = CH₂CH₂X, X = Cl, OMe or OEt; (CH₂)_nOH, n = 2–6; M = W,R = CH₂CH₂X, X= Cl, OMe or OEt; (CH₂)_nOH, n = 2,4–6; CH₂(CF₂)₃CH₂OH} have been prepared from [ML^*(NO)Cl₂] and the appropriate alcohol in the presence of NEt₃ or NaCO₃, and have been characterized by IR, ¹H NMR and mass spectroscopy.     

负载型Sn2(OMe)2Cl2/SiO2催化剂的制备、表征与催化合成碳酸二甲酯

采用表面改性法制备了负载型Sn2(OMe)2Cl2/SiO2双核桥联配合物催化剂,用IR,TPD和微量反应技术研究了催化剂的表面结构、化学吸附性能和反应活性.结果表明,双核桥联配合物Sn2(OMe)2Cl2以O(Me)为桥,Cl为配体,并以Sn-O-Si形式键合到SiO2表面上;CO2与催化剂表面的金属离子Sn4+和桥基配体OMe的O2-形成桥式和甲氧碳酸酯基两种吸附态,CH3OH与催化剂表面的金属离子Sn4+仅形成一种分子吸附态;在413K以下,CO2和CH3OH在Sn2(OMe)2Cl2/SiO2催化剂表面上以近100%的选择性生成碳酸二甲酯;CO2在催化剂表面形成的甲氧碳酸酯基吸附态是生成DMC的关键物种,其与在同一活性中心的分子吸附态甲醇的反应决定了催化剂的活性和产物选择性.     

Oxymetallation : V. The methoxymercuration and tert-butyl peroxymercuration of representative α,β-unsaturated aldehydes and the tert-butyl peroxymercuration of α,β-unsaturated peracetals

The position of mercuration in the products RCH(OMe)CH(HgOAc)CHO, obtained from the methoxymercuration of cinnamaldehyde and crotonaldehyde, and in the products AcOHgCH₂CMe(OR)CHO, from the methoxymercuration and tert-butyl peroxymercuration of methacrolein, is as expected by analogy with related reactions of α,β-unsaturated ketones and esters. Oxymercurations of methacrolein also give the compounds AcOHgCH₂CMe(OMe)CH(OMe)₂ and AcOHgCH_2?CMe(OOBu-t)CH(OOBu-t)OH, formed by subsequent reaction at the aldehyde group. The tert-butyl peroxymercuration of cinnamaldehyde gives only the compound PhCH(OOBu-t)CH(HgOAc)CH(OOBu-t)₂, but here formation of the αβ-unsaturated peracetal, PhCHCHCH(OOBu-t)₂, probably precedes oxymercuration. The compound PhCHCHCH(OOBu-t)₂ and its analogue from methacrolein, CH₂CMeCH(OOBu-t)₂, have been isolated and tert-butyl peroxymercuration of them yields the novel triperoxides PhCH(OOBu-t)CH(HgOAc)CH(OOBu-t)₂ and BrHgCH₂CMe(OOBu-t)CH(OOBu-t)₂ respectively.     

Organoantimony compounds : VIII. Cleavage of Sb—O—Sb bonds in μ—oxybis(triphenyl -chloroantimony) and triphenylantimony oxide by methanol and acetylacetone

SbOSb bonds in (Ph₃ClSb)₂O and PH₃SbO are cleaved readily by methanol and acetylacetone. The reactions provide convenient synthetic routes for Ph₃Sb(OMe)Cl, Ph₃Sb(OMe)₂, Ph₃Sb(acac)Cl, and Ph₃Sb(acac)OH. Characterization of these compounds by infrared, Raman, and ¹H NMR spectral measurements is reported.     

Amorphous Silicon: New Insights into an Old Material

Amorphous silicon is synthesized by treating the tetrahalosilanes SiX₄ (X=Cl, F) with molten sodium in high boiling polar and non‐polar solvents such as diglyme or nonane to give a brown or a black solid showing different reactivities towards suitable reagents. With regards to their technical relevance, their stability towards oxygen, air, moisture, chlorine‐containing reaction partners RCl (R=H, Cl, Me) and alcohols is investigated. In particular, reactions with methanol are a versatile tool to deliver important products. Besides tetramethoxysilane formation, methanolysis of silicon releases hydrogen gas under ambient conditions and is thus suitable for a decentralized hydrogen production; competitive insertion into the MeO?H versus the Me?OH bond either yields H‐ and/or methyl‐substituted methoxy functional silanes. Moreover, compounds, such as Me_nSi(OMe)_4?n (n=0–3) are simply accessible in more than 75 % yield from thermolysis of, for example, tetramethoxysilane over molten sodium. Based on our systematic investigations we identified reaction conditions to produce the methoxysilanes Me_nSi(OMe)_4?n in excellent (n=0:100 %) to acceptable yields (n=1:51 %; n=2:27 %); the yield of HSi(OMe)₃ is about 85 %. Thus, the methoxysilanes formed might possibly open the door for future routes to silicon‐based products.     

Synthesis,functionalization and properties of incompletely condensed “half cube” silsesquioxanes as a potential route to nanoscale Janus particles

Multiple literature reports describe the synthesis of [RSiO(OH)]₄ or [RSiO(ONa)]₄ compounds. Surprisingly, in the majority of cases the OH or ONa groups all lie on the same face of the cyclomers or half cubes. Consequently, it appears possible to couple R containing half cubes with R’ containing half cubes to form bi-functional (Janus) silsesquioxane cages or cubes. We report here synthesis of [PhSiO(ONa)]₄ and [p-IPhSiO(ONa)]₄ half cubes. We thereafter discuss efforts to react the [PhSiO(ONa)]₄ salt with (R = Me, vinyl, and cyclohexyl) RSiCl3 in MeOH to produce the compounds {PhSiO[OSi(OMe)2R]}₄ species which were characterized using traditional spectroscopic procedures. These compounds were then subjected to acid catalyzed hydrolysis tohydrolytically remove the OMe groups to generate Janus cubes. While it is possible to isolate the target compounds, which were also characterized in detail, the yields were lower than expected perhaps because of competitive hydrolytic cleavage of the Si-O-SiR(OMe)₂ linkage.     

Zur reaktion von iminodithiocarbonaten mit carbonsäuren I: Synthese des modellpeptid-derivates Z(L)Ala(L/D)Phe(L)ValOMe

The tripeptide derivative Z(L)Ala(L/D)Phe(L)ValOMe was obtained in 40% yield by reacting (CH₃S)₂CN(L)CH[CH(CH₃)₂]COOCH₃ with the dipeptide derivative Z(L)Ala(L)PheOH and ZnCl₂ at 110°C. The product obtained by bulk condensation contained 9 %, the product obtained utilizing ethylene carbonate as solvent contained 10 % of the diastereomer Z(L)la(D)Phe(L)ValOMe. Separation of diastereomers was achieved by HPLC on a silicagel column.     

Photocatalytic properties of [polymerized n-butyl-o-titanate + hydrogen peroxide] complex on the decomposition of water

The electronic structure of the [pol-Ti(OBu)₄ + H₂O₂] complex, which is formed during the photolysis of water over [pol-Ti(OBu)₄ + CH₃OH] complex on silica gel, is elucidated in detail from the photocatalytic standpoint by DV-Xα cluster calculations. The numerical results reveal the appearance of a localized state (active site) similar to that of the [pol-Ti(OBu)₄ + CH₃OH] complex. The [TiOBu)(OH)(OH)₄]²⁻ cluster, which substitutes a hydroxyl group for the (OOH) group, exhibits an electronic structure very close to that of the [Ti(OBu)(OMe)(OH)₄]²⁻ cluster (A₁ or A₂), which was studied previously. A reduction in photocatalytic activity for the water decomposition is discussed.     

Convenient Synthetic Approach to (2-Aryl-5-phenyl-1,3-oxazol-4-yl)phosphonic Acids and Their Functional Derivatives

Successive treatment of available amidophenacylating agents of the general formula PhCOCH ⋅ ClNHCOAr with trimethyl phosphite and phosphorus pentachloride gave previously unknown (2-aryl-5-phenyl-1,3-oxazol-4-yl)phosphonic dichlorides which are suitable dtarting materials for preparing other phosphorylated oxazoles containing P(O)(OH)₂, P(O)(NHAlk)₂, P(O)(OMe)NHAlk, P(O)(OMe)NAlk₂, and other groups in the 4 position of the heteroring.__________Translated from Zhurnal Obshchei Khimii, Vol. 75, No. 4, 2005, pp. 561–564.Original Russian Text Copyright © 2005 by Belyuga, Brovarets, Drach.     

Complexation of methylparathion and bis(2‐hydroxyethyl)sulfide by the tridentate lewis acid [(o‐C6F4Hg)3]

The interaction of trimeric perflu‐ oro‐ortho‐phenylene mercury ( 1 ) with bis(2‐hydroxy‐ ethyl)sulfide (S((CH₂)₂OH)₂) in dichloromethane and methylparathion (SP(OMe)₂(p‐C₆H₄NO₂)) in 1,2‐dichloroethane leads to the crystallization of [ 1 ⋅ (S((CH₂)₂OH)₂)] and [ 1 ⋅ (μ₃‐SP(OMe)₂(p‐C₆H₄‐ NO₂))₂], respectively. These two adducts have been characterized by elemental analysis and single crystal X‐ray diffraction. The structure of [ 1 ⋅ S((CH₂)₂OH)₂] shows that the bis(2‐hydroxyethyl)sulfide molecule interacts with the mercury centers of 1 by formation of a Hg–S interaction of 3.138(4) Å. Association of the two components is further strengthened by the coordination of one of the oxygen atoms of the bis(2‐hydroxyethyl)sulfide molecule. This oxygen atom interacts simultaneously with three mercury centers of 1 with Hg–O distances ranging from 2.889(8) to 3.142(9) Å. In the lattice, molecules of [ 1 ⋅ (S((CH₂)₂OH)₂)] associate with compact cofacial dimers with Hg–Hg metallophilic contacts of 3.794 Å and 4.076 Å. The structure of [ 1 ⋅ (μ₃‐SP(OMe)₂(p‐C₆H₄NO₂))₂] is that of a 2:1 complex in which two molecules of methylparathion are triply coordinated via their sulfur atom to the mercury centers of 1 on either side of the molecular plane. The Hg–S contacts fall within the range of 3.278 and 3.651 Å. © 2005 Wiley Periodicals, Inc. 16:292–297, 2005; Published online in Wiley InterScience ( www.interscience.wiley.com ). DOI 10.1002/hc.20125     

Polyfluoroorganoboron‐Oxygen Compounds. 5 Feasible Routes to Perfluoroalkyltrimethoxyborates M[CnF2n+1B(OMe)3] (n ≥ 3)

A well applicable preparative method for lithium perfluoroalkyltrimethoxyborates, Li[C_nF_2n+1B(OMe)₃] (n = 3, 4, 6), was elaborated which is based on the reaction of B(OMe)₃ with C_nF_2n+1Li generated from C_nF_2n+1H and t‐BuLi. Alternative perfluoroalkylation reactions of B(OMe)₃ with perfluoropropyllithium generated from C₃F₇I and RLi, perfluoropropylmagnesium bromide, or perfluoropropyltrimethylsilane and potassium fluoride gave less satisfactory results for M[C₃F₇B(OMe)₃]. The conversion of M[C_nF_2n+1B(OMe)₃] salts (M = Li, BrMg) into K[C_nF_2n+1B(OMe)₃] salts and basic properties of the new salts are reported.     

The peptide NCbz‐Val‐Tyr‐OMe and aromatic π–π interactions

The peptide N‐benzyloxycarbonyl‐L‐valyl‐L‐tyrosine methyl ester or NCbz‐Val‐Tyr‐OMe (where NCbz is N‐benzyloxycarbonyl and OMe indicates the methyl ester), C₂₃H₂₈N₂O₆, has an extended backbone conformation. The aromatic rings of the Tyr residue and the NCbz group are involved in various attractive intra‐ and intermolecular aromatic π–π interactions which stabilize the conformation and packing in the crystal structure, in addition to N—H...O and O—H...O hydrogen bonds. The aromatic π–π interactions include parallel‐displaced, perpendicular T‐shaped, perpendicular L‐shaped and inclined orientations.     

Encapsulation of Triphenylene Derivatives in the Hexanuclear Arene Ruthenium Metallo‐Prismatic Cage [Ru6(p‐PriC6H4Me)6(tpt)2(dhbq)3]6+ (tpt = 2,4,6‐tri(pyridin‐4‐yl)‐1,3,5‐triazine,dhbq = 2,5‐dihydroxy‐1,4‐benzoquinonato)

A large cationic triangular metallo‐prism, [Ru₆(p‐PrⁱC₆H₄Me)₆(tpt)₂(dhbq)₃]⁶⁺ ( 1 )⁶⁺, incorporating p‐cymene ruthenium building blocks, bridged by 2,5‐dihydroxy‐1,4‐benzoquinonato (dhbq) ligands, and connected by two 2,4,6‐tri(pyridin‐4‐yl)‐1,3,5‐triazine (tpt) subunits, allows the permanent encapsulation of the triphenylene derivatives hexahydroxytriphenylene, C₁₈H₆(OH)₆ and hexamethoxytriphenylene, C₁₈H₆(OMe)₆. These two cationic carceplex systems [C₁₈H₆(OH)₆⊂ 1 ]⁶⁺ and [C₁₈H₆(OMe)₆⊂ 1 ]⁶⁺ have been isolated as their triflate salts. The molecular structure of these systems has been established by one‐dimensional ¹H ROESY NMR experiments as well as by the single‐crystal structure analysis of [C₁₈H₆(OMe)₆⊂ 1 ][O₃SCF₃]₆.     

The X‐ray Crystal Structures of Hg(C6F4X‐p)2 (X = NH2, OMe,or Me) – Two Examples of Supramolecular Lewis Acid/Base Complexes

The X‐ray crystal structures of Hg(C₆F₄X‐p)₂ (X = NH₂, OMe, or Me) show the compounds to have almost linear C–Hg–C stereochemistry (X = NH₂, 176.3(4)°; X = OMe, 179.5(2)°; X = Me, 176.3(2)°), and the two tetrafluoroaryl rings rotated ca. 52–62° with respect to each other. Substantial conjugation of NH₂ and OMe groups with the aromatic rings is evident from N–C and O–C(Ar) distances. For X = NH₂ or OMe, two weak N(O)–Hg coordination interactions per mercury lead to a two dimensional supramolecular chain structure containing pairs of π‐stacked aromatic rings at near van der Waals contact distances rotated at 62.2° (X = NH₂) or 52.9° (X = OMe) to each other. In Hg(C₆F₄Me‐p)₂, which does not have potential donor atoms, no supramolecular structure is obtained, the molecules being laterally displaced from one another.