Organophosphonates are used as chemical warfare agents, pesticides, and corrosion inhibitors. New materials for the sorption, detection, and decomposition of these compounds are urgently needed. To facilitate materials and application innovation, a better understanding of the interactions between organophosphonates and surfaces is required. To this end, we have used diffuse reflectance infrared Fourier transform spectroscopy to investigate the adsorption geometry of dimethyl methylphosphonate (DMMP) on MoO 3 , a material used in chemical warfare agent filtration devices. We further applied ambient pressure X-ray photoelectron spectroscopy and temperature programmed desorption to study the adsorption and desorption of DMMP. While DMMP adsorbs intact on MoO 3 , desorption depends on coverage and partial pressure. At low coverages under UHV conditions, the intact adsorption is reversible. Decomposition occurs with higher coverages, as evidenced by PCH x and PO x decomposition products on the MoO 3 surface. Heating under mTorr partial pressures of DMMP results in product accumulation.
Ligation
and decomposition of 1,6-hexanedithiol on copper clusters
have been studied by means of temperature-programmed desorption (TPD)
and X-ray photoelectron spectroscopy (XPS). Copper cluster anions
were first made via magnetron sputtering, then size selected and soft
landed into a frozen matrix of 1,6-hexandithiol on highly ordered
pyrolytic graphite (HOPG) maintained at 100 K. After warming up to
298 K, a combination of TPD and XPS were performed to characterize
the newly deposited sample. TPD data shed light upon the adsorption
and decomposition pathways of 1,6-hexanedithiol molecules on copper
clusters. Based on the TPD data, two different binding motifs are
proposed: the dangling motif is with one sulfur atom binding to a
copper cluster, and the bidentate motif is with both sulfur atoms
binding to a copper cluster. Different decomposition products were
observed for each binding motif. A series of hydrogen atom titration
experiments were designed to provide further evidence for the proposed
decomposition mechanism. XPS measurements at varied temperatures agree
well with the TPD profile by confirming the formation of dithiol ligated
copper clusters through Cu–S bond formation, and the decomposition
of them via C–S bond scission. How well the dithiol ligand
can protect the copper clusters from being oxidized is discussed,
and the ligand number per cluster is estimated.
studied here, no monolayer is formed. Instead, the clusters are randomly distributed as expected for particles with zero mobility. These results demonstrate the high potential of cluster deposition for the production of new types of nanostructured surfaces, thin films and nanomaterials.
Size-selected Mon−, Wn−, and Fen− cluster anions are deposited on a weakly interacting substrate (highly oriented pyrolytic graphite) and studied ex-situ using atomic force microscopy. Depending on size, three growth modes can be distinguished. Very small clusters consisting of less than 10–30 atoms behave similar to atoms and coalesce into 3-dimensional bulk-like islands. Medium sized clusters consisting of hundreds of atoms do not coalesce and follow a Stanski-Krastanov growth pattern. At low coverage, an almost perfect monolayer is formed. This is a new finding different from all previous studies on deposited metal clusters. For clusters with several thousands of atoms, the growth pattern again changes. At low coverage, the substrate is dotted with individual clusters, while at high coverage, the surface becomes extremely rough.
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