A. V. Soldatov scite author profile

In the typical NH3-SCR temperature range (100-500 °C), ammonia is one of the main adsorbed species on acidic sites of Cu-SSZ-13 catalyst. Therefore, the study of adsorbed ammonia at high temperature is a key step for the understanding of its role in the NH3-SCR catalytic cycle. We employed different spectroscopic techniques to investigate the nature of the different complexes occurring upon NH3 interaction. In particular, FTIR spectroscopy revealed the formation of different NH3 species, that is, (i) NH3 bonded to copper centers, (ii) NH3 bonded to Brønsted sites, and (iii) NH4(+)·nNH3 associations. XANES and XES spectroscopy allowed us to get an insight into the geometry and electronic structure of Cu centers upon NH3 adsorption, revealing for the first time in Cu-SSZ-13 the presence of linear Cu(+) species in Ofw-Cu-NH3 or H3N-Cu-NH3 configuration.

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X-ray Emission Spectroscopy To Study Ligand Valence Orbitals in Mn Coordination Complexes

Smolentsev

et al. 2009

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We discuss a spectroscopic method to determine the character of chemical bonding and for the identification of metal ligands in coordination and bioinorganic chemistry. It is based on the analysis of satellite lines in x-ray emission spectra that arise from transitions between valence orbitals and the metal ion 1s level (valence-to-core XES). The spectra, in connection with calculations based on density functional theory (DFT), provide information that is complementary to other spectroscopic techniques, in particular x-ray absorption (XANES and EXAFS). The spectral shape is sensitive to protonation of ligands and allows ligands, which differ only slightly in atomic number (e.g. C, N, O...), to be distinguished . A theoretical discussion of the main spectral features is presented in terms of molecular orbitals for a series of Mn model systems: [Mn(H2O)6]2+, [Mn(H2O)5OH]+, [Mn(H2O)5NH2]+ and [Mn(H2O)5NH3]2+. An application of the method, with comparison between theory and experiment, is presented for solvated Mn2+ ion in water and three Mn coordination complexes, namely [LMn(acac)N3]BPh4, [LMn(B2O3Ph2)(ClO4)] and [LMn(acac)N]BPh4 where L represents 1,4,7-trimethyl-1,4,7-triazacyclononane, acac stands for the 2,4-pentanedionate anion and B2O3Ph2 represents the 1,3-diphenyl-1,3-dibora-2-oxapropane-1,3-diolato dianion.

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A. V. Soldatov

Revisiting the nature of Cu sites in the activated Cu-SSZ-13 catalyst for SCR reaction

Interaction of NH₃with Cu-SSZ-13 Catalyst: A Complementary FTIR, XANES, and XES Study

X-ray Emission Spectroscopy To Study Ligand Valence Orbitals in Mn Coordination Complexes

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About

A. V. Soldatov

Revisiting the nature of Cu sites in the activated Cu-SSZ-13 catalyst for SCR reaction

Interaction of NH3with Cu-SSZ-13 Catalyst: A Complementary FTIR, XANES, and XES Study

X-ray Emission Spectroscopy To Study Ligand Valence Orbitals in Mn Coordination Complexes

Contact Info

Product

Resources

About

Interaction of NH₃with Cu-SSZ-13 Catalyst: A Complementary FTIR, XANES, and XES Study