Category: 14187-32-7

Synthetic Route of 14187-32-7, Children learn through play, and they learn more than adults might expect. Science experiments are a great way to spark their curiosity, get their minds active, and encourage them to do something that doesn’t involve a screen. 14187-32-7, C20H24O6. A document type is Article, introducing its new discovery.

The fullerene-crown ether conjugates (±)-1 to (±)-3 with trans-1 ((±)-1), trans-2 ((±)-2), and trans-3 ((±)-3) addition patterns on the C- sphere were prepared by Bingel macrocyclization. The trans-1 derivative (±)- 1 was obtained in 30% yield, together with a small amount of (±)-2 by cyclization of the dibenzo[18]crown-6(DB18C6)-tethered bis-malonate 4 with C60 (Scheme 1). When the crown-ether tether was further rigidified by K+- ion complexation, the yield and selectivity were greatly enhanced, and (±)-1 was obtained as the only regioisomer in 50% yield. The macrocyclization, starting from a mixture of tethered bis-malonates with anti (4) and syn (10) bisfunctionalized DB18C6 moieties, afforded the trans-1 ((±)-1, 15%), trans- 2 ((±)-2, 1.5%), and trans-3 ((±)-3, 20%) isomers (Scheme 2). Variable- temperature 1H-NMR (VT-NMR) studies showed that the DB18C6 moiety in C2- symmetrical (±)-1 cannot rotate around the two arms fixing it to the C- sphere, even at 393 K. The planar chirality of (±)-1 was confirmed in 1H- NMR experiments using the potassium salts of (S)1,1′-binaphthalene-2,2′-diyl phosphate ((±)-(S)-19) or (+)-(1S)-camphor-10-sulfonic acid ((+)-20) as chiral shift reagents (Fig. 1). The DB18C6 tether in (±)-1 is a true covalent template: it is readily removed by hydrolysis or transesterification, which opens up new perspectives for molecular scaffolding using trans-1 fullerene derivatives. Characterization of the products 11 (Scheme 3) and 18 (Scheme 4) obtained by tether removal unambiguously confirmed the trans-1 addition pattern and the out-out geometry of (±)-1. VT-NMR studies established that (±)-2 is a C2-symmetrical out- out trans-2 and (±)-3 a C1-symmetrical in-out trans-3 isomer. Upon changing from (±)-1 to (±)-3, the distance between the DB18C6 moiety and the fullerene surface increases and, correspondingly, rotation of the ionophore becomes increasingly facile. The ionophoric properties of (±)-1 were investigated with an ion-selective electrode membrane (Fig. 2 and Table 2), and K+ was found to form the most stable complex among the alkali-metal ions. The complex between (±)-1 and KPF6 was characterized by X-ray crystal-structure analysis (Figs. 3 and 4), which confirmed the close tangential orientation of the ionophore atop the fullerene surface. Addition of KPF6 to a solution of (±)-1 resulted in a large anodic shift (90 mV) of the first fullerene-centered reduction process, which is attributed to the electrostatic effect of the K- ion bound in close proximity to the C-sphere (Fig. 5). Smaller anodic shifts were measured for the KPF6 complexes of (±)-2 (50 mV) and (±)-3 (40 mV), in which the distance between ionophore and fullerene surface is increased (Table 3). The effects of different alkali- and alkaline-earth-metal ion salts on the redox properties of (±)-1 were investigated (Table 4). These are the first-ever observed effects of cation complexation on the redox properties of the C-sphere in fullerene- crown ether conjugates.

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Chiral Catalysts,
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14187-32-7, Name is Dibenzo-18-crown-6, molecular formula is C20H24O6, belongs to chiral-catalyst compound, is a common compound. In a patnet, once mentioned the new application about 14187-32-7, Product Details of 14187-32-7

Definitive X-ray structures of “separated” versus “contact” ion pairs, together with their spectral (UV-NIR, ESR) characterizations, provide the quantitative basis for evaluating the complex equilibria and intrinsic (self-exchange) electron-transfer rates for the potassium salts of p-dinitrobenzene radical anion (DNB-). Three principal types of ion pairs, K(L)+DNB-, are designated as Classes S, M, and C via the specific ligation of K+ with different macrocyclic polyether ligands (L). For Class S, the self-exchange rate constant for the separated ion pair (SIP) is essentially the same as that of the “free” anion, and we conclude that dinitrobenzenide reactivity is unaffected when the interionic distance in the separated ion pair is r SIP ? 6 A. For Class M, the dynamic equilibrium between the contact ion pair (with rCIP = 2.7 A) and its separated ion pair is quantitatively evaluated, and the rather minor fraction of SIP is nonetheless the principal contributor to the overall electron-transfer kinetics. For Class C, the SIP rate is limited by the slow rate of CIP ? SIP interconversion, and the self-exchange proceeds via the contact ion pair by default. Theoretically, the electron-transfer rate constant for the separated ion pair is well-accommodated by the Marcus/Sutin two-state formulation when the precursor in Scheme 2 is identified as the “separated” inner-sphere complex (ISSIP) of cofacial DNB-/DNB dyads. By contrast, the significantly slower rate of self-exchange via the contact ion pair requires an associative mechanism (Scheme 3) in which the electron-transfer rate is strongly governed by cationic mobility of K(L)+ within the “contact” precursor complex (ISCIP) according to the kinetics in Scheme 4.

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Chiral Catalysts,
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The reaction rate of a catalyzed reaction is faster than the reaction rate of the uncatalyzed reaction at the same temperature.14187-32-7, Name is Dibenzo-18-crown-6, molecular formula is C20H24O6. In a Article，once mentioned of 14187-32-7, SDS of cas: 14187-32-7

New crystalline materials of mixed composition based on the interaction between tetraarylporphyrin and 18-crown-6 derivatives have been prepared and characterized by X-ray diffraction analysis. Free crown ether macrocycles (18- crown-6 and dibenzo-18-crown-6) associate to manganese- or zinc- tetraphenylporphyrin in aqueous solution through a bridging molecule of water which simultaneously coordinates to the axial site of the porphyrin metal core and hydrogen bonds to the oxygens of the crown ether. This ternary mode of self- assembly can lead to the formation of monomeric, oligomeric and stacked polymeric entities, depending on the symmetry of the crown structure and the preferred coordination geometry of the metal ion. Sodium or potassium 18-crown- 6 chlorides were found to be excellent templates for the construction of non- interpenetrating beta-molecular networks from zinc-tetra(4- carboxyphenyl)porphyrin building blocks. The resulting layered motifs incorporate the crown ether moieties within the interporphyrin cavities. These arrays are stabilized by strong hydrogen bonds between the self-complementary carboxylic groups as well as by ion pairing, as their formation is associated with proton transfer from one of the carboxylic groups to the chloride anion and expulsion of hydrochloric acid. Molecules of the methanol solvent, which coordinate axially to the central metal ions of the porphyrin and crown ether moieties in one layer while hydrogen bonding to the carboxylic groups of another layer, contribute to the tight packing of the molecular layers along the third dimension. The experimentally established geometries and packing modes of these aggregates provide useful information for further crystal engineering efforts of networked multi-porphyrin domains.

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Chiral Catalysts,
Chiral catalysts – SlideShare

Application of 14187-32-7, An article , which mentions 14187-32-7, molecular formula is C20H24O6. The compound – Dibenzo-18-crown-6 played an important role in people’s production and life.

Raman and IR spectra of 18-crown-6 with cations were measured for their aqueous solutions and crystals.A Cs symmetry conformation of 18-crown-6 in its complexes with divalent cations was deduced, based on the solvent effect on the spectra of 18-crown-6 and also normal vibration calculation.Conformation analyses by spectral patterns revealed that the electric charge of captured cations determines the conformation of 18-crown-6 in complexes in solutions, while that of the crystals is affected by the ionic diameter of captured cations.

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Chiral Catalysts,
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Reference of 14187-32-7, Catalysts are substances that increase the reaction rate of a chemical reaction without being consumed in the process. 14187-32-7, Name is Dibenzo-18-crown-6, molecular formula is C20H24O6. In a Article，once mentioned of 14187-32-7

The products of the reactions between potassium hexachloroplatinate [K2PtCl6] and 18-crown-6 or dibenzo-18-crown-6 in acetonitrile were studied. Pure crystalline compounds [2K·2(18-crown-6)· 2CH3CN]2+ · [PtCl6]2- · 2H2O, [2K · dibenzo-18-crown-6 · CH3CN]2+ · [PtCl6]2-, and [2K · dibenzo-18-crown-6 · CH3CN]2+ · [Pt2Cl10]2- were obtained. Physicochemical properties of these compounds were studied, and their near- and far-IR IR spectra and thermogravimetric curves were considered. The composition of the complexes is determined by metal : ligand molar ratio and crown ether nature. It was found that acetonitrile is coordinated via the nitrogen atom.

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Chiral Catalysts,
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Chemistry is an experimental science, and the best way to enjoy it and learn about it is performing experiments.Introducing a new discovery about 14187-32-7, Name is Dibenzo-18-crown-6, Application In Synthesis of Dibenzo-18-crown-6.

Luminescence from [(NH4(18-Crown-6))4MnBr4][TlBr4] 2 (1), [(NH4(18-Crown-6))4MnCl4][TlCl4] 2 (2), [(NH4(18-Crown-6))2MnBr4] (3), and [(NH4(18-Crown-6))2MnCl4] (4) was studied in search of new insights regarding crystal defects in 2. Emission from 3 and 4 is normal Mn2+(4T1(4G) ? 6A1); that of 2 (lambdamax ? 520 nm at ca. 300 K and 560 nm at 77 K) is unusual and temperature dependent. Thermal barriers (kJ/mol, assignment): green emission of 1 and 2, T<150 K (1-2, NH4+ rotations), 150250 K (29 kJ/mol, defect-to-Mn2+(4T1(4G)) back energy transfer). Crystal data for 4: Space group P21/c; Z = 4; a = 20.173(1) A; b = 9.0144(8) A; c = 20.821(1) A; beta = 98.782(5); V = 3741.9(8) A3; Rw = 0.059; R = 0.054.

Balanced chemical reaction does not necessarily reveal either the individual elementary reactions by which a reaction occurs or its rate law.Application In Synthesis of Dibenzo-18-crown-6. In my other articles, you can also check out more blogs about 14187-32-7

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Chiral Catalysts,
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Children learn through play, and they learn more than adults might expect. Science experiments are a great way to spark their curiosity, get their minds active, and encourage them to do something that doesn’t involve a screen. 14187-32-7, C20H24O6. A document type is Article, introducing its new discovery., COA of Formula: C20H24O6

Dibenzo-18-crown-6 (DBC) was immobilized on crosslinked polyvinyl alcohol (CPVA) microspheres, resulting in polymer-supported crown ether DBC-CPVA. The complexation adsorption behaviors of DBC-CPVA microspheres towards diverse metal ions were investigated. The experimental results show that among alkali metal ions, the complexation adsorption ability of DBC-CPVA for K+ ion is the strongest, and crown ether-metal complex in 1:1 ratio is formed, exhibiting a high adsorption capacity. The adsorption capacities of alkali metal ions on DBC-CPVA are in the order: K+ ? Na+ > LI+ > Rb+ > Cs+. Among several divalent metal ions, DBC-CPVA exhibits stronger adsorption ability towards Zn2+ and Co2+ ions, and a “sandwich”-type complex is formed probably in a molar ratio of 2:1 between the immobilized DBC and Zn2+ ion as well as between the immobilized DBC and Co2+ ion. The adsorption capacities of the several divalent metal ions on DBC-CPVA are in the order: Zn2+ > Co2+ ? Cd2+ > Cu2+ > Ni2+ > Pb2+. The complexation adsorption is exothermic physical physisorption process, and raising temperature leads to the decrease of the adsorption capacity. At the same time, the entropy during the complexation adsorption decreases, so the adsorption process is driven by the decrease of enthalpy.

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Chiral Catalysts,
Chiral catalysts – SlideShare

The reaction rate of a catalyzed reaction is faster than the reaction rate of the uncatalyzed reaction at the same temperature.14187-32-7, Name is Dibenzo-18-crown-6, molecular formula is C20H24O6. In a Article，once mentioned of 14187-32-7, Quality Control of: Dibenzo-18-crown-6

The heats of reactions between the acyclic and cyclic macro-compounds are determined. The values can be used as a measure of the donor abilities of the macro ligands. Formation of two types of complexes between the macro compounds and SbCl5 is established. The acyclic macro-compounds form 1:1 complexes, whereas the macrocyclic compounds only 1:2 complexes. (C) 2000 Elsevier Science B.V.

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Reference：
Chiral Catalysts,
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Synthetic Route of 14187-32-7, An article , which mentions 14187-32-7, molecular formula is C20H24O6. The compound – Dibenzo-18-crown-6 played an important role in people’s production and life.

Reversible photocontrol of glycosides and glycoconjugates structures is a very attractive approach to modulate, in a spatiotemporal way, the various properties and biological activities of carbohydrates. We have synthesized three new azobenzene-derived glycomacrolactones from thioglycopyranosides. The synthesized cyclic glycoazobenzenes can be reversibly photoisomerized between E and Z isomers with high fatigue resistance. A 1H NMR spectroscopic study shows that E ? Z isomerization of glycomacrocycles induces large conformational change of the macrocyclic structures, without changing sugar 4C1 chair conformation. The Z-glycoazobenzenes can be thermally converted back to the E-isomers. Interestingly, these 16 to 17-membered Z-glycomacrolactones display higher thermal stability than the reported macrocyclic azobenzenes, the half-life varying from 37 to 72 days. The excellent photoswitching property and bistability of the synthesized glycoazobenzenes open a new opportunity for the convergent synthesis of diastereomers of glycomacrocycles. Furthermore, chiroptical properties have been observed for both E and Z glycomacrolactones. The geometry of different isomers of macrocycles has been optimized with DFT calculations. Theoretical CD spectra obtained by TD-DFT suggest that the E and Z glycomacrocycles adopt preferentially (P) helical structure for the azobenzene moiety.

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Reference：
Chiral Catalysts,
Chiral catalysts – SlideShare

Synthetic Route of 14187-32-7, Children learn through play, and they learn more than adults might expect. Science experiments are a great way to spark their curiosity, get their minds active, and encourage them to do something that doesn’t involve a screen. 14187-32-7, C20H24O6. A document type is Article, introducing its new discovery.

A method for the synthesis of complexes of sodium and lithium borohydrides with crown ethers is proposed. The complexes of sodium borohydride with benzo-15-crown-5, 4?-aminobenzo-15-crown-5, dibenzo-18-crown-6, and diaza-18-crown-6 and the complexes of lithium borohydride with benzo-15-crown-5 and dibenzo-18-crown-6 are synthesized. These complexes can be used for the preparation of hydrogen in their reactions with methanol. The complex formation does not affect the purity of hydrogen formed.

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Chiral Catalysts,
Chiral catalysts – SlideShare