A Theoretical and Experimental Study of the Effects of Silyl Substituents in Enantioselective Reactions Catalyzed by Diphenylprolinol Silyl Ether

The effect of silyl substituents in diphenylprolinol silyl ether catalysts was investigated. Mechanistically, reactions catalyzed by diphenylprolinol silyl ether can be categorized into three types: two that involve an iminium ion intermediate, such as for the Michael‐type reaction (type A) and the cycloaddition reaction (type B), and one that proceeds via an enamine intermediate (type C). In the Michael‐type reaction via iminium ions (type A), excellent enantioselectivity is realized when the catalyst with a bulky silyl moiety is employed, in which efficient shielding of a diastereotopic face of the iminium ion is directed by the bulky silyl moiety. In the cycloaddition reaction of iminium ions (type B) and reactions via enamines (type C), excellent enantioselectivity is obtained even when the silyl group is less bulky and, in this case, too much bulk reduces the reaction rate. In other cases, the yield increases when diphenylprolinol silyl ethers with bulky substituents are employed, presumably by suppressing side reactions between the nucleophilic catalyst and the reagent. The conformational behaviors of the iminium and enamine species have been determined by theoretical calculations. These data explain the effect of the bulkiness of the silyl substituent on the enantioselectivity and reactivity of the catalysts.     

Magnitude of CH/O interactions between carbohydrate and water

The interaction energy potentials for six orientations of the fucose–water complex were calculated for evaluating the magnitude of the CH/O interactions in the complex. The calculations show that the C–H bonds of the nonpolar surface of fucose prefer to have contact with the oxygen atom of the water. The substantial attraction exists between the C–H bonds of fucose and water. The interaction energy calculated for the fucose–water complex at the MP2/aug-cc-pVTZ level is −2.55 kcal/mol. The CH/O interactions in the fucose–water complex are significantly larger than those in the cyclohexane–water complex (−1.13 kcal/mol), which shows that the oxygen atoms of fucose enhance the CH/O interactions. The electrostatic and dispersion interactions are responsible for the attraction in the CH/O interactions in the fucose–water complex, while the electrostatic contributions to the attraction in the CH/O interactions in the cyclohexane–water complex is small. The DFT-SAPT calculations also show that the electrostatic interactions are responsible for the larger attraction in the fucose–water complex. These results suggest that the nature of the CH/O interactions between carbohydrate and water is significantly different from that of the CH/O interactions between saturated hydrocarbon and water.     

Rapid synthesis of tin-doped indium oxide microcrystals in supercritical water using hydrazine as reducing agent

Tin-doped indium oxide (ITO) microcrystals were successfully synthesized in supercritical water (SCW) using hydrazine (N₂H₄) as a reducing agent. Using a mixture of tin and indium hydroxides prepared at pH = 9.4 as a precursor, ITO microcrystals were synthesized at temperatures 400–450 °C under pressures 25–30 MPa. Synthesizing in SCW effectively shortened the time required to synthesize the ITO microcrystals to below 30 mins. The effect of reducing agents (ethanol, formic acid, and N₂H₄) and reaction conditions on the formation of ITO particles were investigated, and it was found that N₂H₄, which is superior to ethanol and formic acid, played a key role in the doping of the In₂O₃ structure with Sn⁴⁺ to form ITO particles with a blue color. Addition of N₂H₄ possibly depleted the oxygen in the In(Sn)OOH structure, accelerating the formation of cubic In₂O₃ and introduced Sn⁴⁺ into the structure along with the creation of oxygen vacancies. It was also found that the high temperatures and the properties of the SCW, such as ion product, strongly affected the morphology of the ITO particles and the Sn⁴⁺ doping. Based on these results, a mechanism has been proposed for the synthesis of ITO particles under SCW conditions. This study demonstrates that due to the unique properties of SCW, the synthesis of doped oxides in SCW is a plausible alternative method.     

Intermolecular interactions of nitrobenzene-benzene complex and nitrobenzene dimer: significant stabilization of slipped-parallel orientation by dispersion interaction

The CCSD(T) level interaction energies of eight orientations of nitrobenzene-benzene complexes and nine orientations of nitrobenzene dimers at the basis set limit have been estimated. The calculated interaction energy of the most stable slipped-parallel (C(s)) nitrobenzene-benzene complex was -4.51 kcal/mol. That of the most stable slipped-parallel (antiparallel) (C(2h)) nitrobenzene dimer was -6.81 kcal/mol. The interaction energies of these complexes are significantly larger than that of the benzene dimer. The T-shaped complexes are substantially less stable. Although nitrobenzene has a polar nitro group, electrostatic interaction is always considerably weaker than the dispersion interaction. The dispersion interaction in these complexes is larger than that in the benzene dimer, which is the cause of the preference of the slipped-parallel orientation in these complexes.     

Reaction of OH radical with mono‐, di‐, and trichloroacetaldehyde: an ab initio study

The hydrogen abstraction reactions between chlorine‐substituted acetaldehydes and OH radicals have been investigated by using ab initio molecular orbital theory. Equilibrium geometries and transition‐state structures have been optimized at the (U)MP2/6‐311G(d,p) level. Activation barriers and heats of reaction for different reaction channels have been estimated from the single‐point calculations at the (U)MP2/6‐311G(2df,2p) level. Three, two, and one hydrogen abstraction channel have been found for the mono‐, di‐, and trichloroacetaldehyde, respectively. At a higher temperature region, hydrogen abstraction from the formyl group is found to be the major reaction channel for all the three chloroacetaldehydes. The effect of halogen substitution on reactivity toward hydrogen abstraction has been discussed. © 2001 John Wiley & Sons, Inc. J Comput Chem 22: 1509–1521, 2001     

Kinetics of the hydrogen abstraction reactions of 1,1‐ and 1,2‐difluoroethane with hydroxyl radical: an ab initio study

The hydrogen abstraction reactions of 1,1‐ and 1,2‐difluoroethane with the OH radical have been investigated by the ab initio molecular orbital theory. The geometries of the reactants, products, and transition states have been optimized at the (U)MP2=full level of theory in conjunction with 6‐311G(d,p) basis functions. Single‐point (U)MP2=full with larger basis set, such as 6‐311G(3d,2p), and QCISD(T)=full/6‐311G(d,p) calculations have also been carried out to observe the effects of basis sets utilized and higher order electron correlation. Three and four reaction channels have been identified for 1,1‐ and 1,2‐difluoroethane, respectively. In the case of 1,1‐difluoroethane, hydrogen abstraction from the α‐carbon has been found to be easier than that from the β‐carbon. The barriers of the four reaction channels for 1,2‐difluoroethane are close to each other. Weak hydrogen bonding interactions have been observed between hydroxyl hydrogen and a fluorine atom in the transition states. Rate constants for the reactions of 1,1‐ and 1,2‐difluoroethane with the OH radical have been calculated using the standard transition state theory and found to be in good agreement with the experimental results. © 2000 John Wiley & Sons, Inc. J Comput Chem 21: 1305–1318, 2000