Cyclic peptides containing even numbers of alternating D-and L-amino acids adopt a symmetric ring structure with NH and CO amide functions approximately perpendicular to the average plane of the ring. This results in hydrogen-bonded, -sheet like tubular ensembles by coaxial stacking of rings in which adjacent strands are oriented antiparallel to one another. Starting from a molecular mechanics minimum energy configuration having the C 4 symmetry reported for similar structures, an optimized monomer geometry which retained that symmetry was obtained using density functional theory (DFT). The geometry of the monomer is quite similar to that of stable polypeptides and proteins and the calculated gas-phase harmonic vibrational frequencies are quantitatively reasonable. Two monomers were then brought together coaxially, with adjacent strands arranged antiparallel, creating a dimer of D 4 symmetry. Dimer energy was then minimized with respect to ring separation along, and relative rotation of one ring with respect to the other about, the common C 4 axis. The interstrand separation in this dimer model is reasonable in comparison with experimental values reported for stable -sheet polypeptides and proteins as are the harmonic vibrational frequencies. An approximation to the harmonic N-H‚‚‚O stretching frequency calculated for this dimer model was also physically reasonable by comparison to the interchain motion calculated for -sheet polypeptides from analysis of experimental vibrational frequencies. Though synthesis of the molecules in this study has not been reported, they serve as excellent models for the analysis of ring structure and for isolating the role of backbone-backbone hydrogen bonds in the stacking process for similar assemblies. This study provides theoretical support for experimental work on more complex systems, and the DFT calculations are among the largest ever for the study of molecular systems using double valence single polarization basis sets.
The soil of a coastal Mexican refinery is quite contaminated, especially by hydrocarbons, with detected concentrations up to 130000 mg kg(-1) as TPHs (total petroleum hydrocarbons). The main sources of contamination are pipelines, valves, and old storage tanks, besides the land disposal of untreated hydrocarbon sediments derived from the cleaning of storage tanks. A health risk assessment (HRA) was carried out in order to measure the risk hazard indexes and clean-up standards for the refinery soil. HRA suggested the following actions to be taken: benzene concentrations must be reduced in eight of the 16 studied refinery zones to 0.0074-0.0078 mg kg(-1). Also, vanadium concentration must be reduced in two zones up to a concentration of 100 mg kg(-1). In only one of all of the studied zones, benzo(a)pyrene concentration must be reduced to 0.1 mg kg(-1). After 1 yr, TPHs showed a diminution of about 52%. Even though TPHs concentrations were variable, during 1999 the average concentrations were as much as 15.5 times the goal concentration. For year 2000, TPHs concentrations were only 7.4-fold the proposed value. For the 1999-2000 period, PAHs (polycyclic aromatic hydrocarbons) concentrations decreased by 82%. Some PAHs with 2, 3, 4, and 5 aromatic rings were removed up to 100% values.
The effect of the substituents on the electronic properties of graphene nanoflakes possessing high spin ground state, has been studied at D3bj dispersion corrected B3LYP/cc-pVDZ, and CAS/6-31G(d) levels of theory. The results of DFT and CAS calculations qualitatively agree with each other. The substituents affect the nature of the ground state. The electron withdrawing substituents, especially these with cyano groups favor the singlet ground state. The effect of the electron donating groups is more erratic. They can promote both high and low spin ground states. The side groups affect the topology of singly occupied molecular orbitals, modifying exchange interactions. Hence, depending on the type of substituents, one or another spin state could be favored. The calculations confirmed that the origin of the high spin ground state in these systems is attributed to the nondisjoint character of the occupied orbitals causing strong exchange coupling between the electrons. The substitution of the nanoflake increases the band gap and their reorganization energies.
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