A simple molecular model of adsorption chromatography. XI. Adsorption of aromatic nitro compounds with various polar groups on magnesium silicate

Summary Aromatic nitro compounds with hydroxyl, amino, hydrazino, aldehyde, methoxy and halogen substituents were chromatographed in liquid-solid systems of the type cyclohexane+polar solvent — magnesium silicate or Florisil. The effect of the molecular structure on the slopes of the log k vs. log X_S and R_M vs. log X_S plots (X_S — mole fraction of the polar component in the developing solvent) is interpreted in terms of a molecular adsorption model elaborated originally for silica. For some solutes TLC data are compared with the results of analogous column experiments.Part X: Ref. [1].     

Experimental studies of the liquid junction potential between electrolyte solutions in different solvents part IV. A study using mixed-solvent salt bridges

The problem of the liquid junction potential (ljp) between different solvents was studied by measuring the emf's of a cell with a mixed-solvent salt bridge: Ag65 mM AgClO₄, 5 mM Et₄NClO₄ (S₁);1 mM Et₄ NClO₄ (S₁); 0.1 M MX (S₃ + S′₃); 1 mM Et₄NClO₄ (S₂);5 mM Et₄NClO₄, 5 mM AgClO₄ (S₂)6Ag. For 130 different combinations of solvents S₁, S₂, and (S₃+S′₃), the emf's were measured by changing the composition of (S₃ + S′₃) from pure S₃ to S′₃. Though there were exceptions, the emf's in many cases changed linearly or nearly linearly with the volume fraction of the mixed solvents. It was considered that the results were obtained because the component of the Ijp which was due to the solvent-solvent interactions at the mixed solvent/pure solvent junctions often changed in linear or near-linear relations with the volume fraction of the mixed solvent. A preliminary experiment showed some possibility of similar relations also to hold for mixed solvent/mixed solvent junctions.     

Optimized Method for the Determination of Flavonoid Glycosides and Aglycones

The relationship R_M=f (log % S; S- modifier) of several flavonoids and their sugar derivatives was examined by using chromatographic systems chosen by preliminary experiments. The dependence for flavonoid aglycones was flat in the whole mobile phase concentration. Two types of the R_M=f (log % S) plots, related to the size of sugar molecule, were found. For glycosides with smaller sugar moiety (arabinose or glucose) the plot was almost parallel, while plots of derivatives with larger sugar moiety (rutose) were convergent. After plotting the relationship R_M=f (log % S), even if standards are not available, it is possible to qualify the examined compound as containing single or complex sugar moiety. For all mentioned above compounds the R_M=f (log %S) values were given. Silica gel Si60 was used as polar adsorbent. Mobile phase composition was determined in preliminary experiments; it was composed of two solvents: methanol in ethyl acetate in increasing concentration of methanol: 5 – 20%.     

Solvent composition effects in column and thin layer chromatography of aromatic nitro compounds on alumina

Summary The relationship between R _M and the concentration of the polar solvent in the moving phase was investigated for a number of aromatic nitro compounds with additional polar groups (amino, methoxy, carbomethoxy, aldehyde). TLC data were correlated with analogous column chromatography results. Linear R _M (logk') vs. logX _S relationships obtained for both techniques are interpreted in terms of a molecular model of adsorption.     

Metastable transitions in the mass spectra of ketals and ketones. Competition between loss of small and large radicals

An investigation of competing metastable transitions in the mass spectra of ethylene ketals R_SR_LC(OCH₂)₂ (where R_L is a larger n-alkyl group than R_S) has established that in most cases R_S is lost with a lower activation energy than R_L. This technique has also been applied to ketones R_SR_LC?O, to show again that R_S is usually lost with the lower activation energy (thus supporting earlier data based on relative daughter ion abundances at the threshold). In the classes of compounds so far investigated, although [M⁺ ? R_S] ions are formed with lower activation energies than [M⁺ ? R_L] ions, the ion yield of [M⁺ ? R_S] ions is anomalously low from ions of high internal energy. Factors which may influence the [M⁺ ? R_S]/[M⁺ ? R_L] ratio of daughter ion intensities are examined. It is suggested that at the threshold [M⁺ ? R_S] and [M⁺ ? R_L] ions may be formed with rearrangement, or from an electronic state that cannot be effectively populated from molecular ions of high internal energies.     

A simple molecular model of adsorption chromatography XIV. RF or RM? Secondary retention effects in thin-layer chromatography

Summary It is demonstrated that although the R_F values are directly related to the separations obtained, the R_M values are more convenient in the theory of optimization of chromatograpohic systems. Graphs for direct plotting of R_F values in the R_M scale are shown in both logarithmic and linear solvent composition scale. The effects of preadsorption of the solvent vapours and of simultaneous partition betwen the mobile and the stagnant developing solvent on the retention vs. compostion plots are illustrated. Examples are shown for crossing retentions vs. solvent composition plots.Part XIII: ref [1].     

Radical Copolymerization of Acrylic Monomers. II Effect of Solvent on Radical Copolymerization of Methyl Methacrylate and Styrene

The influence of various solvents on the copolymerization behavior of methyl methacrylate with styrene has been investigated. In these systems there is a significant solvent effect on both r_S and r_M which may be attributed to changes in the dielectric constant of the solvents used. The calculated relative reactivity of the polystyryl radical towards the methyl methacrylate monomer increases with increasing solvent polarity, whereas the reactivity of poly(methyl methacrylate) radical towards styrene monomer decreases. The results obtained are discussed taking into account the behavior of both monomers in homopolymerization with the same experimental conditions as in copolymerization.     

Generalized correlations for molecular weight and concentration dependence of zero-shear viscosity of high polymer solutions

Data are presented to show that two correlations of viscosity–concentration data are useful representations for data over wide ranges of molecular weight and up to at least moderately high concentrations for both good and fair solvents. Low molecular weight polymer solutions (below the critical entanglement molecular weight M_c) generally have higher viscosities than predicted by the correlations. One correlation is η_sp/c[η] versus k′[η], where η_sp is specific viscosity, c is polymer concentration, [η] is intrinsic viscosity, and k′ is the Huggins constant. A standard curve for good solvent systems has been defined up to k′[η]c ≈? 3. It can also be used for fair solvents up to k′[η]c ≈? 1.25· low estimates are obtained at higher values. A simpler and more useful correlation is η_R versus c[η], where η_R is relative viscosity. Fair solvent viscosities can be predicted from the good solvent curve up to c[η] ≈? 3, above which estimates are low. Poor solvent data can also be correlated as η_R versus c[η] for molecular weights below 1 to 2 × 10⁵.     

Determination of Chain Transfer Constant for Solvent When the Viscosity of the Polymerizing System Is Considered Important

Abstract

The chain transfer constant of the polymethyl methacrylate radical for N,N-dimethylaniline was determined in two solvents, benzene and dimethyl phthalate. Plots were made using1/P_n=k_t°R_p/k_p ²[M]²η + C_S1 [S₁]/[M] + C_S2 [S₂]/[M] +C_M where η=viscosity of monomer-solvents mixture, k_t°=rate coefficient of termination when η=1 cP, S₁=benzene or dimethyl phthalate, S₂=N,N-dimethylaniline, and other symbols have their usual meanings. The plots agreed well for the two solvents. If the plots were made without considering the viscosity term, two separate lines resulted for the two solvents. Thus it is essential to consider the viscosity of the polymerizing system in the analysis of chain transfer reactions when the termination reaction is diffusion-controlled and the viscosities of the monomer and solvent differ markedly.     

A simple molecular model of adsorption chromatography. XIII. Comparison of solvation effects in liquid-solid and liquid-liquid systems

Summary R_Mvs solvent composition plots of three quinoline bases are compared for analogous liquid-liquid and liquid-solid systems. For the heptane+heptanone-2-water system for which the variation of R_M(log k′) values with concentration of heptanone-2 is due to solvation effects in the mobile phase, the slope of the plots was much smaller than in the case of the heptane + heptanone-2-silica system. This is considered as evidence that solvation in the mobile phase cannot play the decisive role in the adsorption equilibrium. On the other hand, the relationships can be interpreted in terms of competitive interactions of the solutes and polar solvent (heptanone-2) with the surface silanol groups, as the main molecular mechanism. Part XII: Ref. [1].     

Computational study of SN2 reactions promoted by crown ether: Contact ion pair versus solvent‐separated ion pair mechanism

We examined by quantum chemical methods the mechanism of S_N2 reaction using metal bromide MBr (M = Na, K, Cs) and KX (X= F, Cl) in CH₃CN promoted by crown ether (18‐crown‐6). We focus on whether the metal salts react as a contact ion pair (CIP; M⁺ and X^– in close contact) or as a solvent‐separated ion pair (SSIP; M⁺ and X^– at large distance). In SSIP mechanism, X^– is removed far enough from M⁺ for the metal salt to be considered as “separated” by the effects of the crown ether and the solvent. In the CIP picture, conversely, the coordination of 18‐crown‐6 to M⁺ is not sufficient to overcome the powerful Coulombic interactions between M⁺ and X^–. We find that the CIP route is favored for S_N2 bromination processes using MBr (M = Na, K, Cs). For S_N2 reaction using KF, the feasibility of the two pathways is essentially equal, whereas for S_N2 chlorination by KCl the SSIP route is predicted to be favored.     

Precise Manipulation of Temperature-Driven Chirality Switching of Molecular Universal Joints through Solvent Mixing

Three chiral bicyclic pillar[5]arene derivatives termed as molecular universal joints (MUJs), were synthesized and separated enantiomerically. These MUJs showed temperature-driven chirality switching in certain solvents. Herein, it is demonstrated that temperature-driven chirality switching could also be realized by mixing two miscible organic solvents, in each of which chirality inversion is not accomplishable. Additionally, solvent mixing drastically varied the inversion temperature of the MUJs, for example, from far below zero to room temperature. Moreover, the temperature-driven S_p/R_p to R_p/S_p chirality switching direction could be reversed by the solvent mixing and it was critically controlled by the mixing ratios of the two solvents. These observations allowed precise manipulation of the chirality switching behavior of the MUJs. Such a chirality switching was ascribed to the influences of solvent and temperature on the in–out equilibrium of the side rings, which is delicately controlled by several processes, including the solvation/desolvation and the inclusion/exclusion of the side rings and solvent molecules. Crucially, the solvent mixing introduced new supramolecular processes, in particular the desolvation of solvent molecules from the mixed solvent system and the solvation of the side ring by the mixed solvent, which significantly disturbed the original in–out equilibrium of MUJs and drastically switched the entropy and enthalpy changes of conformational interconversion.     

Quasi-column chromatography of barbituric acid derivatives II. Separation on Non-polar adsorbents using binary water-organic solvent mixtures as the mobile phase

Summary Twenty barbituric acid derivatives having four different types of substitution were separated in TLC-S chambers. Using non-polar adsorbents (silanized silica gel or silica gel coated with paraffin oil) and binary water-organic solvent mixtures as the mobile phase. Linear relationships between R_M and the concentration of the organic solvent were observed for the majority of the investigated compounds. The non-polar absorbents ensure a better separation than untreated silica gel especially for the therapeutically useful C₅ disubstituted barbiturates. The results can be used for the optimization of the systems for the chromatography of barbiturates. The R_f values were correlated with the number of carbon atoms of the substitutions, molecular connectivity and a parameter associated with the molecular volume. The best correlations were obtained for this last parameter.     

Dependence of the thermodynamic characteristics of the complexation of alanine-18-crown-6 on the composition of water-ethanol solvent

Standard thermodynamic parameters (Δ_r G○, Δ_r H○, TΔ_r S○) for the complexation reaction of 18-crown-6 ether (18C6) with D,L-alanine (Ala) in mixed water-ethanol (H₂O-EtOH) solvents are calculated from the data of calorimetric titrations performed at T = 298.15 K. It is established that an increase in the concentration of EtOH in mixed solvent leads to a rise in stability and an increase in the exothermicity of [Ala18C6] molecular complex formation; changes in the energetics of reaction upon a change in the solvent composition are determined by changes in the solvation state of 18C6, which is typical of the reactions of molecular complex formation of 18C6 with D,L-alanine and glycine in water-organic solvents.     

Solvent effect on the radical polymerization of di-n-butyl itaconate

Solvent effect on the polymerization of di-n-butyl itaconate (DBI) with dimethyl azobisisobutyrate (MAIB) was investigated at 50 and 61°C. The solvents used were found to affect significantly the polymerization. The polymerization rate (R_p) and the molecular weight of the resulting polymer are lower in more polar solvents. The initiation rate (R_i) by MAIB, however, shows a trend of being rather higher in polar solvents. The stationary state concentration of propagating poly(DBI) radical was determined by ESR in seven solvents. The rate constants of propagation (k_p) and termination (k_t) were evaluated by using R_p, R_i, and the polymer radical concentration observed. The k_p value decreases fairly with increasing polarity of the solvent used, whereas k_t is not so influenced by the solvents. The solvent effect on k_p is explained in terms of a difference in the environment around the terminal radical center of the growing chain. Copolymerization of DBI with styrene (St) was also examined in three solvents with different physical properties. The poly(DBI) radical shows a lower reactivity toward St in a more polar solvent.     

Theoretical investigation on identical anionic halide‐exchange SN2 reaction processes on N‐haloammonium cation NH3X+ (X = F,Cl, Br,and I)

CCSD(T) calculations have been used for identically nucleophilic substitution reactions on N‐haloammonium cation, X^? + NH₃X⁺ (X = F, Cl, Br, and I), with comparison of classic anionic S_N2 reactions, X^? + CH₃X. The described S_N2 reactions are characterized to a double curve potential, and separated charged reactants proceed to form transition state through a stronger complexation and a charge neutralization process. For title reactions X^? + NH₃X⁺, charge distributions, geometries, energy barriers, and their correlations have been investigated. Central barriers ΔE for X^? + NH₃X⁺ are found to be lower and lie within a relatively narrow range, decreasing in the following order: Cl (21.1 kJ/mol) > F (19.7 kJ/mol) > Br (10.9 kJ/mol) > I (9.1 kJ/mol). The overall barriers ΔE relative to the reactants are negative for all halogens: ?626.0 kJ/mol (F), ?494.1 kJ/mol (Cl), ?484.9 kJ/mol (Br), and ?458.5 kJ/mol (I). Stability energies of the ion–ion complexes ΔE_comp decrease in the order F (645.6 kJ/mol) > Cl (515.2 kJ/mol) > Br (495.8 kJ/mol) > I (467.6 kJ/mol), and are found to correlate well with halogen Mulliken electronegativities (R² = 0.972) and proton affinity of halogen anions X^? (R² = 0.996). Based on polarizable continuum model, solvent effects have investigated, which indicates solvents, especially polar and protic solvents lower the complexation energy dramatically, due to dually solvated reactant ions, and even character of double well potential in reactions X^? + CH₃X has disappeared. © 2011 Wiley Periodicals, Inc. Int J Quantum Chem, 2011     

Retention behaviour of model solutes on mixed silica-magnesia adsorbents by TLC. Comparison with the adsorption properties of Florisil

Summary The retention behaviour of positional isomers (phenols, aniline derivatives, quinoline bases) and polyaromatic hydrocarbons on mixed silica-magnesia layers is examined using various binary eluents (ethyl acetate, dioxane or 2-propanol in n-heptane). The influence of magnesia content in mixed adsorbents and concentration of polar modifier in the eluent on retention were investigated. Results obtained in chosen systems were compared with retention of solutes on Florisil layers using the same eluents by theR _{M Florisil} vsR _{M mix} correlations. Analysis of the structural effects of solutes and the position of points onR _{M Florisil} vsR _{M mix} diagrams enables comparison of chemical character and distribution of active centers on Florisil and mixed adsorbent surfaces.     

Crystallization-based optical resolution of 1,1′-binaphthalene-2,2′-dicarboxylic acid via 1-phenylethylamides: control by the molecular structure and dielectric property of solvent

In the recrystallization of a diastereomeric mixture of amides (RS_a,S)-1 formed from racemic 1,1′-binaphthalene-2,2′-dicarboxylic acid and (S)-1-phenylethylamine, either of the diastereomers crystallizes out as a diastereomerically pure form, depending on the solvent employed; sterically undemanding solvents, acetone, dichloromethane, and acetonitrile, afford crystals formulated as (S_a,S)-1·solvent with an exception of ethanol, which affords (R_a,S)-1·EtOH, while sterically bulkier solvents afford (R_a,S)-1 including no solvent. The stereoselectivity can be rationalized by the crystal structures. A dielectrically controlled resolution (DCR) can also be carried out by using mixed solvents, which contain, for example, 25 vol % of acetone and varying ratios of hexane and 1-propanol in total 75 vol %; (S_a,S)-1·acetone is deposited as crystals from the solvents with a dielectric constant (ε) range 8.9 ? ε ? 10.2, while (R_a,S)-1 is deposited from the solvents with 14.8 ? ε ? 20.3.