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Title Electronic Rearrangement upon the Hydrolyzation of Aqueous Formaldehyde Studied by Core-Electron Spectroscopies.
Author/s Niklas Ottosson, Emad F Aziz, Henrik Bergersen, Wandared Pokapanich, Gunnar Öhrwall, Svante Svensson, Wolfgang Eberhardt, Olle Björneholm
Department/s Max-laboratory
Full-text Full text is not available in this archive
Alternative location (URL) http://dx.doi.org/10.1021/jp80... Restricted Access (Alternative Location)
Publication/Series Journal of physical chemistry. B
Publishing year 2008
Volume 112
Issue 51
Pages 16642 - 16646
Document type Journal article
Status published
Quality controlled yes
Language English
Publisher American Chemical Society
Abstract English We have combined near edge X-ray absorption fine structure (NEXAFS) spectroscopy and X-ray photoelectron spectroscopy (XPS) to study the electronic rearrangement associated with the hydrolyzation of formaldehyde to methanediol in aqueous solution. The spectra are contrasted against those of aqueous formamide and urea, which are structurally similar but do not undergo hydrolysis in solution. We have recently demonstrated that the hydrolyzation of formaldehyde is manifested in the oxygen 1s NEXAFS spectrum by the disappearance of the oxygen 1s --> pi* absorption line. This is a characteristic signature that the CO double bond has been broken. In the present study we extend our investigation to include carbon 1s NEXAFS and XPS spectra of the three solutions. The carbon NEXAFS spectra show the C 1s --> pi* absorption line for each solute except for formaldehyde. Moreover, the carbon 1s photoelectron spectra exhibit a single peak for each solute. These observations point to a near complete hydrolyzation of formaldehyde, whereas formamide and urea remain intact in the solution. The analysis is further supported by density functional theory (DFT) calculations, showing a C 1s chemical shift of approximately 1.0 eV between hydrolyzed and nonhydrolyzed forms, which would give distinguishable features in the photoemission spectrum, if coexisting forms were present in the solutions.
Subject Chemistry
ISBN/ISSN/Other ISSN: 1520-6106

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  • Last updated 24 Apr 2013