High-Resolution X-ray Photoelectron Spectroscopy of an IrO2(110) Film on Ir(100).

High-resolution X-ray photoelectron spectroscopy (XPS) and density functional theory (DFT) were used to characterize IrO2(110) films on Ir(100) with stoichiometric as well as OH-rich terminations. Core-level Ir 4f and O 1s peaks were identified for the undercoordinated Ir and O atoms and bridging and on-top OH groups at the IrO2(110) surfaces. Peak assignments were validated by comparison of the core-level shifts determined experimentally with those computed using DFT, quantitative analysis of the concentrations of surface species, and the measured variation of the Ir 4f peak intensities with photoelectron kinetic energy. We show that exposure of the IrO2(110) surface to O2 near room temperature produces a large quantity of on-top OH groups because of reaction of background H2 with the surface. The peak assignments made in this study can serve as a foundation for future experiments designed to utilize XPS to uncover atomic-level details of the surface chemistry of IrO2(110).

Molecular chemisorption of N2 on IrO2(110).

We investigated adsorption of N2 on stoichiometric and O-rich IrO2(110) surfaces using temperature programmed desorption (TPD) experiments and density functional theory (DFT) calculations. TPD shows that N2 desorbs predominantly from the stoichiometric-IrO2(110) surface in a well-defined peak at 270 K for N2 coverages below about 0.5 ML and that a shoulder centered near 235 K develops in the N2 TPD traces as the coverage approaches saturation, indicating that adsorbed N2 molecules destabilize at high N2 coverages. Experiments of N2 adsorption onto O-rich IrO2(110) surfaces provide evidence that N2 adsorbs exclusively on the coordinatively unsaturated Ir atoms (Ircus) of the surface and that pre-adsorbed O-atoms ("on-top" oxygen) stabilize adsorbed N2 molecules, causing the main N2 TPD peak to shift toward higher temperature with increasing oxygen coverages. Consistent with prior results, our DFT calculations predict that an N2 molecule preferentially adsorbs into an upright configuration on an Ircus atom of the IrO2(110) surface and achieves a binding energy of about 100 kJ/mol. The computed binding energy agrees well with our experimental estimate of ∼90 kJ/mol for low N2 coverages on stoichiometric IrO2(110). The DFT calculations also quantitatively reproduce the observed stabilization of N2 by co-adsorption on-top O-atoms and predict the destabilization of N2 on IrO2(110) as the N2 adlayer becomes crowded at high coverages.

Effects of non-local exchange on core level shifts for gas-phase and adsorbed molecules.

Density functional theory calculations are often used to interpret experimental shifts in core level binding energies. Calculations based on gradient-corrected (GC) exchange-correlation functionals are known to reproduce measured core level shifts (CLS) of isolated molecules and metal surfaces with reasonable accuracy. In the present study, we discuss a series of examples where the shifts calculated within a GC-functional significantly deviate from the experimental values, namely the CLS of C 1s in ethyl trifluoroacetate, Pd 3d in PdO and the O 1s shift for CO adsorbed on PdO(101). The deviations are traced to effects of the electronic self-interaction error with GC-functionals and substantially better agreements between calculated and measured CLS are obtained when a fraction of exact exchange is used in the exchange-correlation functional.

Differentiation of the IL-3-dependent NFS-60 cell line and adaption to growth in macrophage colony-stimulating factor.

Macrophage CSF (M-CSF) induces responsive bone marrow precursors into rapid growth and differentiation to mature macrophages. Available cell lines that depend on M-CSF for growth are well differentiated and rather adherent. We investigated the effects of M-CSF on immature myeloid cell lines as models of the marrow precursors. The murine line NFS-60 requires IL-3 for growth and also responds to granulocyte-CSF and granulocyte-macrophage-CSF. Cultures of one NFS-60 subline, when switched from IL-3 to 10% L cell conditioned media, a source of M-CSF, or purified M-CSF, frequently acquired large, adherent cells. The adherent cells grew slowly in the presence of M-CSF, in contrast to the majority population of small, round, rapidly growing cells. The large cells had properties of differentiated macrophages that were absent in the nonadherent cells. Cells with macrophage phenotype were not observed in IL-3-supported cultures over many passages. A subline was derived from NFS-60 that grew rapidly and continuously in human or murine M-CSF as round, nonadherent cells. The line, called M-NFS-60, responded well to M-CSF and IL-3, weakly to granulocyte-CSF and not at all to murine granulocyte-macrophage-CSF, IL-4, or human IL-1. A mAb to human M-CSF specifically inhibited only M-NFS-60 proliferation induced by the human growth factor, whether produced by mammalian or bacterial cells. This study shows two effects of M-CSF on the IL-3-dependent NFS-60 line. Upon first exposure to M-CSF, cells may undergo global differentiation to slowly replicating macrophages in conditions we have not been able to define. The more common effect is rapid growth of immature myeloid cells like the bone marrow precursors, but with a block to differentiation. Thus, these cells may be useful as models of M-CSF-induced differentiation, and of permanently maintained macrophage precursors.

Inducible production of human macrophage growth factor, CSF-1.

A panel of human cell lines was screened for production of colony-stimulating factor-1 (CSF-1) using a specific radioreceptor assay and criterion of macrophage colony growth in mouse bone marrow culture. The pancreatic carcinoma lines MIA PaCa and PANC were found to secrete high levels of CSF-1. In a bone marrow proliferation assay, the activities from these two lines were blocked by a CSF-1 specific neutralizing antiserum, confirming the predominant content of this macrophage growth factor. MIA PaCA cells stopped secreting CSF-1 when transferred to various serum-free media. Serum-free production could be reinitiated by phorbol myristic acetate (PMA). Purified CSF-1 from serum-free MIA PaCa cells stimulated the formation of 14-day colonies from total and nonadherent mononuclear human bone marrow cells. Most of the colonies consisted exclusively of large, dispersed macrophages that were intensely stained for nonspecific esterase. Although similar numbers of human 14-day colonies were stimulated by CSF-1 and other CSFs, more CSF-1 was required for the proliferation of human as compared with murine bone marrow progenitors. Northern analysis of mRNA from induced-MIA PaCa cells, using a human CSF-1 oligonucleotide probe, revealed multiple species of CSF-1 mRNA ranging from 1.5 to 4.5 kilobases (kb). Uninduced, serum-free cultures showed only the largest mRNA species, suggesting that serum removal interfered with CSF-1 mRNA processing related to synthesis and/or secretion of the protein. Regulation of the production of CSF-1 may be an important physiological process in hematopoiesis and macrophage functioning.