We present comprehensive measurements of the C (carbon) K edge near-edge X-ray absorption (NEXAFS)
spectra of all 20 amino acids commonly occurring in nature. Qualitative trends among the spectra of amino
acids with similar chemical character are identified and spectral features are compared with extensive ab
initio calculations. The contributions of individual units and substitutional groups have been determined to
explore their fingerprinting character using the building block concept. Several such units are found. Two
that give particularly clear features in the C 1s NEXAFS spectra are the carboxyl group (which can be clearly
identified by a pronounced structure due to the C 1s→π*C
O transition with maximum at 288.65(5) eV) and
modified phenol rings in aromatic amino acids (which give sharp C 1s→π*C
C structures). The latter transitions
are located around 285 eV, and their shape is specific for each aromatic amino acid. Other building blocks,
such as the CNH
n
group and the CH, CC, CO, CN pair bonds, are also identified, although their characteristic
features are less pronounced in the C K edge spectra than the carboxylic and aromatic structures. This study
provides the basis for rigorous assignment of the NEXAFS spectra of the amino acids, and will be helpful in
developing X-ray absorption spectroscopy for quantitative analysis of proteins.
An experimental and theoretical study of the electronic structure of copper phthalocyanine (CuPc) molecule is presented. We performed x-ray photoemission spectroscopy (XPS) and photoabsorption [x-ray absorption near-edge structure (XANES)] gas phase experiments and we compared the results with self-consistent field, density functional theory (DFT), and static-exchange theoretical calculations. In addition, ultraviolet photoelectron spectra (UPS) allowed disentangling several outer molecular orbitals. A detailed study of the two highest occupied orbitals (having a(1u) and b(1g) symmetries) is presented: the high energy resolution available for UPS measurements allowed resolving an extra feature assigned to vibrational stretching in the pyrrole rings. This observation, together with the computed DFT electron density distributions of the outer valence orbitals, suggests that the a(1u) orbital (the highest occupied molecular orbital) is mainly localized on the carbon atoms of pyrrole rings and it is doubly occupied, while the b(1g) orbital, singly occupied, is mainly localized on the Cu atom. Ab initio calculations of XPS and XANES spectra at carbon K edge of CuPc are also presented. The comparison between experiment and theory revealed that, in spite of being formally not equivalent, carbon atoms of the benzene rings experience a similar electronic environment. Carbon K-edge absorption spectra were interpreted in terms of different contributions coming from chemically shifted C 1s orbitals of the nonequivalent carbon atoms on the inner ring of the molecule formed by the sequence of CN bonds and on the benzene rings, respectively, and also in terms of different electronic distributions of the excited lowest unoccupied molecular orbital (LUMO) and LUMO+1. In particular, the degenerate LUMO appears to be mostly localized on the inner pyrrole ring.
Ab initio periodic calculations and classical molecular dynamics (MD) simulations were performed to investigate the adsorption mode of alanine and a number of short peptides, in particular two peptides, alanine-glutamic acid and alanine-lysine, taken as model systems for the ionic self-complementary oligopeptide EAK16-II, onto TiO(2) (110) rutile surface, and their conformational characteristics upon adsorption. The atomistic description of the rutile surface and its interactions with water and peptide molecules were based on ab initio calculations, the TIP3P water model, the AMBER force field, and available parameters. By comparison with ab initio calculations, it is shown that MD simulations of reasonable duration can describe the main characteristics of the peptide-TiO(2) surface interaction in solution, at least on a short time scale. Atom-atom radial distribution functions, atom-surface distances, backbone and side chain dihedral angle distributions, and peptide-surface interaction energies have been analyzed. Once adsorbed onto the TiO(2) rutile surface by a bidentate interaction of both carboxyl oxygens with two adjacent Ti atoms, the small peptide studied showed a clear propensity to remain there and undergo relatively limited hinge-bending motions.
The valence and core level photoelectron spectra of glycine, proline, and methionine in the gas phase have been investigated by VUV and soft X-ray radiation. The outer valence band photoemission spectra are similar to previously reported He I spectra, although relative peak intensities are different due to the different photon energy. We extended the spectral range to include the inner valence region. The carbon, nitrogen, and oxygen 1s as well as the sulfur 2p core level spectra of these amino acids have been measured and the states identified. Valence band spectra of proline have been recorded as a function of temperature, and they provide information about the relative populations of the lowest energy conformers.
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