Your search keyword '"P. Bluhm"' showing total 62 results

1. Core-Level Photoelectron Angular Distributions at the Liquid–Vapor Interface

Author

Dupuy, Rémi, Thürmer, Stephan, Richter, Clemens, Buttersack, Tillmann, Trinter, Florian, Winter, Bernd, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Chemistry, General Chemistry, Chemical sciences

Abstract

ConspectusPhotoelectron spectroscopy (PES) is a powerful tool for the investigation of liquid-vapor interfaces, with applications in many fields from environmental chemistry to fundamental physics. Among the aspects that have been addressed with PES is the question of how molecules and ions arrange and distribute themselves within the interface, that is, the first few nanometers into solution. This information is of crucial importance, for instance, for atmospheric chemistry, to determine which species are exposed in what concentration to the gas-phase environment. Other topics of interest include the surface propensity of surfactants, their tendency for orientation and self-assembly, as well as ion double layers beneath the liquid-vapor interface. The chemical specificity and surface sensitivity of PES make it in principle well suited for this endeavor. Ideally, one would want to access complete atomic-density distributions along the surface normal, which, however, is difficult to achieve experimentally for reasons to be outlined in this Account. A major complication is the lack of accurate information on electron transport and scattering properties, especially in the kinetic-energy regime below 100 eV, a pre-requisite to retrieving the depth information contained in photoelectron signals.In this Account, we discuss the measurement of the photoelectron angular distributions (PADs) as a way to obtain depth information. Photoelectrons scatter with a certain probability when moving through the bulk liquid before being expelled into a vacuum. Elastic scattering changes the electron direction without a change in the electron kinetic energy, in contrast to inelastic scattering. Random elastic-scattering events usually lead to a reduction of the measured anisotropy as compared to the initial, that is, nascent PAD. This effect that would be considered parasitic when attempting to retrieve information on photoionization dynamics from nascent liquid-phase PADs can be turned into a powerful tool to access information on elastic scattering, and hence probing depth, by measuring core-level PADs. Core-level PADs are relatively unaffected by effects other than elastic scattering, such as orbital character changes due to solvation. By comparing a molecule's gas-phase angular anisotropy, assumed to represent the nascent PAD, with its liquid-phase anisotropy, one can estimate the magnitude of elastic versus inelastic scattering experienced by photoelectrons on their way to the surface from the site at which they were generated. Scattering events increase with increasing depth into solution, and thus it is possible to correlate the observed reduction in angular anisotropy with the depth below the surface along the surface normal.We will showcase this approach for a few examples. In particular, our recent works on surfactant molecules demonstrated that one can indeed probe atomic distances within these molecules with a high sensitivity of ∼1 Å resolution along the surface normal. We were also able to show that the anisotropy reduction scales linearly with the distance along the surface normal within certain limits. The limits and prospects of this technique are discussed at the end, with a focus on possible future applications, including depth profiling at solid-vapor interfaces.

Published

2023

2. Influence of Excess Charge on Water Adsorption on the BiVO4(010) Surface

Author

Wang, Wennie, Favaro, Marco, Chen, Emily, Trotochaud, Lena, Bluhm, Hendrik, Choi, Kyoung-Shin, van de Krol, Roel, Starr, David E, and Galli, Giulia

Subjects

Engineering, Chemical Sciences, Physical Chemistry, General Chemistry, Chemical sciences

Abstract

We present a combined computational and experimental study of the adsorption of water on the Mo-doped BiVO4(010) surface, revealing how excess electrons influence the dissociation of water and lead to hydroxyl-induced alterations of the surface electronic structure. By comparing ambient pressure resonant photoemission spectroscopy (AP-ResPES) measurements with the results of first-principles calculations, we show that the dissociation of water on the stoichiometric Mo-doped BiVO4(010) surface stabilizes the formation of a small electron polaron on the VO4 tetrahedral site and leads to an enhanced concentration of localized electronic charge at the surface. Our calculations demonstrate that the dissociated water accounts for the enhanced V4+ signal observed in ambient pressure X-ray photoelectron spectroscopy and the enhanced signal of a small electron polaron inter-band state observed in AP-ResPES measurements. For ternary oxide surfaces, which may contain oxygen vacancies in addition to other electron-donating dopants, our study reveals the importance of defects in altering the surface reactivity toward water and the concomitant water-induced modifications to the electronic structure.

Published

2022

3. Ambient pressure X-ray photoelectron spectroscopy study of room-temperature oxygen adsorption on Cu(100) and Cu(111)

Author

Liu, Bo-Hong, Huber, Maximilian, van Spronsen, Matthijs A, Salmeron, Miquel, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Chemistry, Applied Physics

Abstract

We investigated the room-temperature chemisorption of oxygen on Cu(1 0 0) and Cu(1 1 1) using ambient-pressure X-ray photoelectron spectroscopy (APXPS). A shoulder-to-shoulder comparison between the oxygen-gas titration on the two surfaces reveals that Cu(1 0 0) is the more active for oxygen dissociative chemisorption when the surfaces are clean. The (2 2 × 2)R45o missing-row reconstruction appears in Cu(1 0 0)’s LEED image after about 104 Langmuir of oxygen exposure, whereas on Cu(1 1 1), no long-range ordering was observed throughout the whole experiment. An oxide layer consisting of cuprous and cupric oxide shows up on Cu(1 1 1) at an oxygen exposure that is significantly lower than for Cu(1 0 0). This observation suggests that the presence of (2 2 × 2)R45o missing-row reconstruction layer slows down Cu(1 0 0) oxidation. Literature has widely reported that surface morphology influences the copper oxidation process. This study provides an XPS demonstration that copper surface oxide formation in O2 at room temperature depends on the surface crystallographic orientation.

Published

2022

4. Simultaneous ambient pressure x-ray photoelectron spectroscopy and grazing incidence x-ray scattering in gas environments

Author

Kersell, Heath, Chen, Pengyuan, Martins, Henrique, Lu, Qiyang, Brausse, Felix, Liu, Bo-Hong, Blum, Monika, Roy, Sujoy, Rude, Bruce, Kilcoyne, Arthur, Bluhm, Hendrik, and Nemšák, Slavomír

Subjects

Chemical Sciences, Physical Chemistry, physics.ins-det, physics.chem-ph, Physical Sciences, Engineering, Applied Physics, Chemical sciences, Physical sciences

Abstract

We have developed an experimental system to simultaneously measure surface structure, morphology, composition, chemical state, and chemical activity for samples in gas phase environments. This is accomplished by simultaneously measuring x-ray photoelectron spectroscopy (XPS) and grazing incidence x-ray scattering in gas pressures as high as the multi-Torr regime while also recording mass spectrometry. Scattering patterns reflect near-surface sample structures from the nano-scale to the meso-scale, and the grazing incidence geometry provides tunable depth sensitivity of structural measurements. Scattered x rays are detected across a broad range of angles using a newly designed pivoting-UHV-manipulator for detector positioning. At the same time, XPS and mass spectrometry can be measured, all from the same sample spot and under ambient conditions. To demonstrate the capabilities of this system, we measured the chemical state, composition, and structure of Ag-behenate on a Si(001) wafer in vacuum and in O2 atmosphere at various temperatures. These simultaneous structural, chemical, and gas phase product probes enable detailed insights into the interplay between the structure and chemical state for samples in gas phase environments. The compact size of our pivoting-UHV-manipulator makes it possible to retrofit this technique into existing spectroscopic instruments installed at synchrotron beamlines. Because many synchrotron facilities are planning or undergoing upgrades to diffraction limited storage rings with transversely coherent beams, a newly emerging set of coherent x-ray scattering experiments can greatly benefit from the concepts we present here.

Published

2021

5. Simultaneous ambient pressure x-ray photoelectron spectroscopy and grazing incidence x-ray scattering in gas environments.

Author

Kersell, Heath, Chen, Pengyuan, Martins, Henrique, Lu, Qiyang, Brausse, Felix, Liu, Bo-Hong, Blum, Monika, Roy, Sujoy, Rude, Bruce, Kilcoyne, Arthur, Bluhm, Hendrik, and Nemšák, Slavomír

Subjects

physics.ins-det, physics.chem-ph, Applied Physics, Physical Sciences, Chemical Sciences, Engineering

Abstract

We have developed an experimental system to simultaneously measure surface structure, morphology, composition, chemical state, and chemical activity for samples in gas phase environments. This is accomplished by simultaneously measuring x-ray photoelectron spectroscopy (XPS) and grazing incidence x-ray scattering in gas pressures as high as the multi-Torr regime while also recording mass spectrometry. Scattering patterns reflect near-surface sample structures from the nano-scale to the meso-scale, and the grazing incidence geometry provides tunable depth sensitivity of structural measurements. Scattered x rays are detected across a broad range of angles using a newly designed pivoting-UHV-manipulator for detector positioning. At the same time, XPS and mass spectrometry can be measured, all from the same sample spot and under ambient conditions. To demonstrate the capabilities of this system, we measured the chemical state, composition, and structure of Ag-behenate on a Si(001) wafer in vacuum and in O2 atmosphere at various temperatures. These simultaneous structural, chemical, and gas phase product probes enable detailed insights into the interplay between the structure and chemical state for samples in gas phase environments. The compact size of our pivoting-UHV-manipulator makes it possible to retrofit this technique into existing spectroscopic instruments installed at synchrotron beamlines. Because many synchrotron facilities are planning or undergoing upgrades to diffraction limited storage rings with transversely coherent beams, a newly emerging set of coherent x-ray scattering experiments can greatly benefit from the concepts we present here.

Published

2021

6. Identifying Ionic and Electronic Charge Transfer at Oxide Heterointerfaces

Author

Rose, Marc‐André, Šmíd, Břetislav, Vorokhta, Mykhailo, Slipukhina, Ivetta, Andrä, Michael, Bluhm, Hendrik, Duchoň, Tomáš, Ležaić, Marjana, Chambers, Scott A, Dittmann, Regina, Mueller, David N, and Gunkel, Felix

Subjects

Chemical Sciences, Physical Chemistry, Engineering, Physical Sciences, Materials Engineering, Condensed Matter Physics, 2D electron-gases, charge-transfer, in situ spectroscopy, mesoscopic transport, oxide heterointerfaces, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

The ability to tailor oxide heterointerfaces has led to novel properties in low-dimensional oxide systems. A fundamental understanding of these properties is based on the concept of electronic charge transfer. However, the electronic properties of oxide heterointerfaces crucially depend on their ionic constitution and defect structure: ionic charges contribute to charge transfer and screening at oxide interfaces, triggering a thermodynamic balance of ionic and electronic structures. Quantitative understanding of the electronic and ionic roles regarding charge-transfer phenomena poses a central challenge. Here, the electronic and ionic structure is simultaneously investigated at the prototypical charge-transfer heterointerface, LaAlO3 /SrTiO3 . Applying in situ photoemission spectroscopy under oxygen ambient, ionic and electronic charge transfer is deconvoluted in response to the oxygen atmosphere at elevated temperatures. In this way, both the rich and variable chemistry of complex oxides and the associated electronic properties are equally embraced. The interfacial electron gas is depleted through an ionic rearrangement in the strontium cation sublattice when oxygen is applied, resulting in an inverse and reversible balance between cation vacancies and electrons, while the mobility of ionic species is found to be considerably enhanced as compared to the bulk. Triggered by these ionic phenomena, the electronic transport and magnetic signature of the heterointerface are significantly altered.

Published

2021

7. Identification of antiviral antihistamines for COVID-19 repurposing

Author

Reznikov, Leah R, Norris, Michael H, Vashisht, Rohit, Bluhm, Andrew P, Li, Danmeng, Liao, Yan-Shin J, Brown, Ashley, Butte, Atul J, and Ostrov, David A

Subjects

Biochemistry and Cell Biology, Medicinal and Biomolecular Chemistry, Chemical Sciences, Biological Sciences, Prevention, Clinical Research, Emerging Infectious Diseases, Infectious Diseases, Vaccine Related, Biodefense, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Good Health and Well Being, Angiotensin-Converting Enzyme 2, Animals, Antiviral Agents, Catalytic Domain, Chlorocebus aethiops, Drug Repositioning, HEK293 Cells, Histamine Antagonists, Humans, Ligands, Protein Binding, Receptors, Histamine, Receptors, sigma, SARS-CoV-2, Vero Cells, COVID-19 Drug Treatment, Angiotensin converting Enzyme-2, Sigma-1 receptor, Repurposing, Docking, Medical Biochemistry and Metabolomics, Biochemistry & Molecular Biology, Biochemistry and cell biology, Medicinal and biomolecular chemistry

Abstract

There is an urgent need to identify therapies that prevent SARS-CoV-2 infection and improve the outcome of COVID-19 patients. Although repurposed drugs with favorable safety profiles could have significant benefit, widely available prevention or treatment options for COVID-19 have yet to be identified. Efforts to identify approved drugs with in vitro activity against SARS-CoV-2 resulted in identification of antiviral sigma-1 receptor ligands, including antihistamines in the histamine-1 receptor binding class. We identified antihistamine candidates for repurposing by mining electronic health records of usage in population of more than 219,000 subjects tested for SARS-CoV-2. Usage of diphenhydramine, hydroxyzine and azelastine was associated with reduced incidence of SARS-CoV-2 positivity in subjects greater than age 61. We found diphenhydramine, hydroxyzine and azelastine to exhibit direct antiviral activity against SARS-CoV-2 in vitro. Although mechanisms by which specific antihistamines exert antiviral effects is not clear, hydroxyzine, and possibly azelastine, bind Angiotensin Converting Enzyme-2 (ACE2) and the sigma-1 receptor as off-targets. Clinical studies are needed to measure the effectiveness of diphenhydramine, hydroxyzine and azelastine for disease prevention, for early intervention, or as adjuvant therapy for severe COVID-19.

Published

2021

8. Identifying Ionic and Electronic Charge Transfer at Oxide Heterointerfaces.

Author

Rose, Marc-André, Šmíd, Břetislav, Vorokhta, Mykhailo, Slipukhina, Ivetta, Andrä, Michael, Bluhm, Hendrik, Duchoň, Tomáš, Ležaić, Marjana, Chambers, Scott A, Dittmann, Regina, Mueller, David N, and Gunkel, Felix

Subjects

2D electron-gases, charge-transfer, in situ spectroscopy, mesoscopic transport, oxide heterointerfaces, Physical Sciences, Chemical Sciences, Engineering, Nanoscience & Nanotechnology

Abstract

The ability to tailor oxide heterointerfaces has led to novel properties in low-dimensional oxide systems. A fundamental understanding of these properties is based on the concept of electronic charge transfer. However, the electronic properties of oxide heterointerfaces crucially depend on their ionic constitution and defect structure: ionic charges contribute to charge transfer and screening at oxide interfaces, triggering a thermodynamic balance of ionic and electronic structures. Quantitative understanding of the electronic and ionic roles regarding charge-transfer phenomena poses a central challenge. Here, the electronic and ionic structure is simultaneously investigated at the prototypical charge-transfer heterointerface, LaAlO3 /SrTiO3 . Applying in situ photoemission spectroscopy under oxygen ambient, ionic and electronic charge transfer is deconvoluted in response to the oxygen atmosphere at elevated temperatures. In this way, both the rich and variable chemistry of complex oxides and the associated electronic properties are equally embraced. The interfacial electron gas is depleted through an ionic rearrangement in the strontium cation sublattice when oxygen is applied, resulting in an inverse and reversible balance between cation vacancies and electrons, while the mobility of ionic species is found to be considerably enhanced as compared to the bulk. Triggered by these ionic phenomena, the electronic transport and magnetic signature of the heterointerface are significantly altered.

Published

2021

9. Orientation of acetic acid hydrogen bonded to acetate terminated TiO2(110)

Author

Dover, Coinneach Mackenzie, Grinter, David C, Yim, Chi Ming, Muryn, Christopher A, Bluhm, Hendrik, Salmeron, Miquel, and Thornton, Geoff

Subjects

Chemical Sciences, Physical Chemistry, Model photocatalysis, rutile TiO2(110), acetic acid, ambient pressure photoemission, NEXAFS, Condensed Matter Physics, Quantum Physics, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Condensed matter physics, Quantum physics

Abstract

Acetic acid is a common pollutant for which photocatalytic degradation over titania provides a mitigating strategy. Knowledge of the bonding of acetate/acetic acid to this substrate is needed to aid interpretation of the photocatalytic data. In this work we use ambient pressure near edge X-ray absorption fine structure to measure the coverage and geometry of acetate in the TiO2(110) contact layer as well as acetic acid in an additional layer. A saturation coverage of 0.5 monolayers in both layers is found up to an acetic acid pressure of 10−1 Torr at 266 K. The geometry of acetate appears to be unchanged by adsorption of an additional layer of acetic acid, with the contact layer involving a majority acetate species bidentate bonded to neighboring Ti5c sites and a minority acetate species bonded in a perpendicular geometry. Acetic acid has a similar geometry dictated by hydrogen bonding to the contact layer as well as the substrate.

Published

2020

10. Water-polyamide chemical interplay in desalination membranes explored by ambient pressure X-ray photoelectron spectroscopy

Author

Gericke, Sabrina M, Mulhearn, William D, Goodacre, Dana E, Raso, Joseph, Miller, Daniel J, Carver, Lauryn, Nemšák, Slavomír, Karslıoğlu, Osman, Trotochaud, Lena, Bluhm, Hendrik, Stafford, Christopher M, and Buechner, Christin

Subjects

Chemical Engineering, Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Chemical Physics

Abstract

Reverse osmosis using aromatic polyamide membranes is currently the most important technology for seawater desalination. The performance of reverse osmosis membranes is highly dependent on the interplay of their surface chemical groups with water and water contaminants. In order to better understand the underlying mechanisms of these membranes, we study ultrathin polyamide films that chemically resemble reverse osmosis membranes, using ambient pressure X-ray photoelectron spectroscopy. This technique can identify the functional groups at the membrane-water interface and allows monitoring of small shifts in the electron binding energy that indicate interaction with water. We observe deprotonation of free acid groups and formation of a 'water complex' with nitrogen groups in the polymer upon exposure of the membrane to water vapour. The chemical changes are reversed when water is removed from the membrane. While the correlation between functional groups and water uptake is an established one, this experiment serves to understand the nature of their chemical interaction, and opens up possibilities for tailoring future materials to specific requirements.

Published

2020

11. Water-polyamide chemical interplay in desalination membranes explored by ambient pressure X-ray photoelectron spectroscopy.

Author

Gericke, Sabrina M, Mulhearn, William D, Goodacre, Dana E, Raso, Joseph, Miller, Daniel J, Carver, Lauryn, Nemšák, Slavomír, Karslıoğlu, Osman, Trotochaud, Lena, Bluhm, Hendrik, Stafford, Christopher M, and Buechner, Christin

Subjects

Chemical Physics, Physical Sciences, Chemical Sciences, Engineering

Abstract

Reverse osmosis using aromatic polyamide membranes is currently the most important technology for seawater desalination. The performance of reverse osmosis membranes is highly dependent on the interplay of their surface chemical groups with water and water contaminants. In order to better understand the underlying mechanisms of these membranes, we study ultrathin polyamide films that chemically resemble reverse osmosis membranes, using ambient pressure X-ray photoelectron spectroscopy. This technique can identify the functional groups at the membrane-water interface and allows monitoring of small shifts in the electron binding energy that indicate interaction with water. We observe deprotonation of free acid groups and formation of a 'water complex' with nitrogen groups in the polymer upon exposure of the membrane to water vapour. The chemical changes are reversed when water is removed from the membrane. While the correlation between functional groups and water uptake is an established one, this experiment serves to understand the nature of their chemical interaction, and opens up possibilities for tailoring future materials to specific requirements.

Published

2020

12. Water adsorption on vanadium oxide thin films in ambient relative humidity

Author

Goodacre, Dana, Blum, Monika, Buechner, Christin, Hoek, Harmen, Gericke, Sabrina M, Jovic, Vedran, Franklin, Joseph B, Kittiwatanakul, Salinporn, Söhnel, Tilo, Bluhm, Hendrik, and Smith, Kevin E

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Physical Sciences, Chemical Physics, Chemical sciences, Physical sciences

Abstract

In this work, ambient pressure x-ray photoelectron spectroscopy (APXPS) is used to study the initial stages of water adsorption on vanadium oxide surfaces. V 2p, O 1s, C 1s, and valence band XPS spectra were collected as a function of relative humidity in a series of isotherm and isobar experiments. Experiments were carried out on two VO2 thin films on TiO2 (100) substrates, prepared with different surface cleaning procedures. Hydroxyl and molecular water surface species were identified, with up to 0.5 ML hydroxide present at the minimum relative humidity, and a consistent molecular water adsorption onset occurring around 0.01% relative humidity. The work function was found to increase with increasing relative humidity, suggesting that surface water and hydroxyl species are oriented with the hydrogen atoms directed away from the surface. Changes in the valence band were also observed as a function of relative humidity. The results were similar to those observed in APXPS experiments on other transition metal oxide surfaces, suggesting that H2O-OH and H2O-H2O surface complex formation plays an important role in the oxide wetting process and water dissociation. Compared to polycrystalline vanadium metal, these vanadium oxide films generate less hydroxide and appear to be more favorable for molecular water adsorption.

Published

2020

13. Water adsorption on vanadium oxide thin films in ambient relative humidity.

Author

Goodacre, Dana, Blum, Monika, Buechner, Christin, Hoek, Harmen, Gericke, Sabrina M, Jovic, Vedran, Franklin, Joseph B, Kittiwatanakul, Salinporn, Söhnel, Tilo, Bluhm, Hendrik, and Smith, Kevin E

Subjects

Chemical Physics, Physical Sciences, Chemical Sciences, Engineering

Abstract

In this work, ambient pressure x-ray photoelectron spectroscopy (APXPS) is used to study the initial stages of water adsorption on vanadium oxide surfaces. V 2p, O 1s, C 1s, and valence band XPS spectra were collected as a function of relative humidity in a series of isotherm and isobar experiments. Experiments were carried out on two VO2 thin films on TiO2 (100) substrates, prepared with different surface cleaning procedures. Hydroxyl and molecular water surface species were identified, with up to 0.5 ML hydroxide present at the minimum relative humidity, and a consistent molecular water adsorption onset occurring around 0.01% relative humidity. The work function was found to increase with increasing relative humidity, suggesting that surface water and hydroxyl species are oriented with the hydrogen atoms directed away from the surface. Changes in the valence band were also observed as a function of relative humidity. The results were similar to those observed in APXPS experiments on other transition metal oxide surfaces, suggesting that H2O-OH and H2O-H2O surface complex formation plays an important role in the oxide wetting process and water dissociation. Compared to polycrystalline vanadium metal, these vanadium oxide films generate less hydroxide and appear to be more favorable for molecular water adsorption.

Published

2020

14. Quantitative Characterization of a Desalination Membrane Model System by X‑ray Photoelectron Spectroscopy

Author

Buechner, Christin, Gericke, Sabrina M, Trotochaud, Lena, Karslıoǧlu, Osman, Raso, Joseph, and Bluhm, Hendrik

Subjects

Chemical Engineering, Macromolecular and Materials Chemistry, Engineering, Chemical Sciences, Chemical Physics

Abstract

Aromatic polyamide films form the active layer in reverse osmosis desalination membranes. Despite widespread use of this technology, it suffers from low rejection rates for certain water contaminants and from membrane fouling. Through a better understanding of the fundamental surface chemical processes during reverse osmosis desalination, advances in membrane and material design are expected. The recent invention of a molecular layer-by-layer (mLbL) preparation technique [ Johnson , P. M. ; Molecular Layer-by-Layer Deposition of Highly Crosslinked Polyamide Films . J. Polym. Sci., Part B: Polym. Phys. 2012 , 50 ( 3 ), 168 - 173 ] yields films that are sufficiently smooth to warrant investigation with high-resolution microscopy and spectroscopy methods. We present high-resolution, quantitative X-ray photoelectron spectroscopy (XPS) data on the surface chemistry of ultrathin polyamide films that can serve as a model system for desalination membranes. We show that a quantitative analysis of the XPS spectra gives information about the functional groups of the film as well as other compounds present due to the synthesis under ambient conditions. Unpolymerized functional groups are identified and aid in understanding the degree of cross-linking. Investigation of polymers with synchrotron-based XPS requires taking beam-induced changes into account. We quantify X-ray beam damage and show that beam damage to the polyamide is limited, allowing long-term investigation of thin polyamide films. Characterizing mLbL-grown films via high-resolution XPS is the basis for a better understanding of the chemical interplay of polyamide surface functional groups with the major components of desalination systems.

Published

2019

15. Water (Non-)Interaction with MoO3

Author

Head, Ashley R, Gattinoni, Chiara, Trotochaud, Lena, Yu, Yi, Karslıoğlu, Osman, Pletincx, Sven, Eichhorn, Bryan, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Chemistry, Engineering, Technology, Chemical sciences

Abstract

Molybdenum(VI) oxide (MoO3) is used in a number of technical processes such as gas filtration and heterogeneous catalysis. In these applications, the adsorption and dissociation of water on the surface can influence the chemistry of MoO3 and thus the course of heterogeneous reactions. We use ambient pressure X-ray photoelectron spectroscopy to study the interaction of water with a stoichiometric MoO3 surface and a MoO3 surface that features oxygen defects and hydroxyl groups. The experimental results are supported by density functional theory calculations. We show that on a stoichiometric MoO3(010) surface, where Mo sites are unavailable, water adsorption is strongly disfavored. However, the introduction of surface species, which can interact with the lone pairs on the water O atom, e.g., Mo5+ atoms or surface OH groups, promotes water adsorption. Dissociation of water is favored at unsaturated Mo sites, i.e., at oxygen vacancies, while water adsorbs molecularly at hydroxyl sites.

Published

2019

16. Decomposing electronic and lattice contributions in optical pump – X-ray probe transient inner-shell absorption spectroscopy of CuO

Author

Mahl, Johannes, Neppl, Stefan, Roth, Friedrich, Borgwardt, Mario, Saladrigas, Catherine, Toulson, Benjamin, Cooper, Jason, Rahman, Tahiyat, Bluhm, Hendrik, Guo, Jinghua, Yang, Wanli, Huse, Nils, Eberhardt, Wolfgang, and Gessner, Oliver

Subjects

Chemical Sciences, Physical Chemistry, Chemical Physics, Chemical sciences

Abstract

Electronic and lattice contributions to picosecond time-resolved X-ray absorption spectra (trXAS) of CuO at the oxygen K-edge are analyzed by comparing trXAS spectra, recorded using excitation wavelengths of 355 nm and 532 nm, to steady-state, temperature-dependent XAS measurements. The trXAS spectra at pump-probe time-delays ≥150 ps are dominated by lattice heating effects. Insight into the temporal evolution of lattice temperature profiles on timescales up to 100s of nanoseconds after laser excitation are reported, on an absolute temperature scale, with a temporal sensitivity and a spatial selectivity on the order of 10s of picoseconds and 10s of nanometers, respectively, effectively establishing an "ultrafast thermometer". In particular, for the 532 nm experiment at ∼5 mJ cm-2 fluence, both the initial sample temperature and its dynamic evolution are well captured by a one-dimensional thermal energy deposition and diffusion model. The thermal conductivity k = (1.3 ± 0.4) W m-1 K-1 derived from this model is in good agreement with the literature value for CuO powder, kpowder = 1.013 W m-1 K-1. For 355 nm excitation, a quantitative analysis of the experiments is hampered by the large temperature gradients within the probed sample volume owing to the small UV penetration depth. The impact of the findings on mitigating or utilizing photoinduced lattice temperature changes in future X-ray free electron laser (XFEL) experiments is discussed.

Published

2019

17. Water (Non-)Interaction with MoO3.

Author

Head, Ashley R, Gattinoni, Chiara, Trotochaud, Lena, Yu, Yi, Karslıoğlu, Osman, Pletincx, Sven, Eichhorn, Bryan, and Bluhm, Hendrik

Subjects

Chemical Sciences, Engineering, Technology, Physical Chemistry

Abstract

Molybdenum(VI) oxide (MoO3) is used in a number of technical processes such as gas filtration and heterogeneous catalysis. In these applications, the adsorption and dissociation of water on the surface can influence the chemistry of MoO3 and thus the course of heterogeneous reactions. We use ambient pressure X-ray photoelectron spectroscopy to study the interaction of water with a stoichiometric MoO3 surface and a MoO3 surface that features oxygen defects and hydroxyl groups. The experimental results are supported by density functional theory calculations. We show that on a stoichiometric MoO3(010) surface, where Mo sites are unavailable, water adsorption is strongly disfavored. However, the introduction of surface species, which can interact with the lone pairs on the water O atom, e.g., Mo5+ atoms or surface OH groups, promotes water adsorption. Dissociation of water is favored at unsaturated Mo sites, i.e., at oxygen vacancies, while water adsorbs molecularly at hydroxyl sites.

Published

2019

18. Decomposing electronic and lattice contributions in optical pump - X-ray probe transient inner-shell absorption spectroscopy of CuO.

Author

Mahl, Johannes, Neppl, Stefan, Roth, Friedrich, Borgwardt, Mario, Saladrigas, Catherine, Toulson, Benjamin, Cooper, Jason, Rahman, Tahiyat, Bluhm, Hendrik, Guo, Jinghua, Yang, Wanli, Huse, Nils, Eberhardt, Wolfgang, and Gessner, Oliver

Subjects

Physical Chemistry, Chemical Engineering, Macromolecular and Materials Chemistry, Chemical Physics, Chemical Sciences

Abstract

Electronic and lattice contributions to picosecond time-resolved X-ray absorption spectra (trXAS) of CuO at the oxygen K-edge are analyzed by comparing trXAS spectra, recorded using excitation wavelengths of 355 nm and 532 nm, to steady-state, temperature-dependent XAS measurements. The trXAS spectra at pump-probe time-delays ≥150 ps are dominated by lattice heating effects. Insight into the temporal evolution of lattice temperature profiles on timescales up to 100s of nanoseconds after laser excitation are reported, on an absolute temperature scale, with a temporal sensitivity and a spatial selectivity on the order of 10s of picoseconds and 10s of nanometers, respectively, effectively establishing an "ultrafast thermometer". In particular, for the 532 nm experiment at ∼5 mJ cm-2 fluence, both the initial sample temperature and its dynamic evolution are well captured by a one-dimensional thermal energy deposition and diffusion model. The thermal conductivity k = (1.3 ± 0.4) W m-1 K-1 derived from this model is in good agreement with the literature value for CuO powder, kpowder = 1.013 W m-1 K-1. For 355 nm excitation, a quantitative analysis of the experiments is hampered by the large temperature gradients within the probed sample volume owing to the small UV penetration depth. The impact of the findings on mitigating or utilizing photoinduced lattice temperature changes in future X-ray free electron laser (XFEL) experiments is discussed.

Published

2019

19. Identifying the Role of Dynamic Surface Hydroxides in the Dehydrogenation of Ti-Doped NaAlH4

Author

White, James L, Rowberg, Andrew JE, Wan, Liwen F, Kang, ShinYoung, Ogitsu, Tadashi, Kolasinski, Robert D, Whaley, Josh A, Baker, Alexander A, Lee, Jonathan RI, Liu, Yi-Sheng, Trotochaud, Lena, Guo, Jinghua, Stavila, Vitalie, Prendergast, David, Bluhm, Hendrik, Allendorf, Mark D, Wood, Brandon C, and Gabaly, Farid El

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, hydrogen storage, ambient-pressure X-ray photoelectron spectroscopy, ab initio simulation, sodium aluminum hydride, surface chemistry, Nanoscience & Nanotechnology, Chemical sciences, Physical sciences

Abstract

Solid-state metal hydrides are prime candidates to replace compressed hydrogen for fuel cell vehicles due to their high volumetric capacities. Sodium aluminum hydride has long been studied as an archetype for higher-capacity metal hydrides, with improved reversibility demonstrated through the addition of titanium catalysts; however, atomistic mechanisms for surface processes, including hydrogen desorption, are still uncertain. Here, operando and ex situ measurements from a suite of diagnostic tools probing multiple length scales are combined with ab initio simulations to provide a detailed and unbiased view of the evolution of the surface chemistry during hydrogen release. In contrast to some previously proposed mechanisms, the titanium dopant does not directly facilitate desorption at the surface. Instead, oxidized surface species, even on well-protected NaAlH4 samples, evolve during dehydrogenation to form surface hydroxides with differing levels of hydrogen saturation. Additionally, the presence of these oxidized species leads to considerably lower computed barriers for H2 formation compared to pristine hydride surfaces, suggesting that oxygen may actively participate in hydrogen release, rather than merely inhibiting diffusion as is commonly presumed. These results demonstrate how close experiment-theory feedback can elucidate mechanistic understanding of complex metal hydride chemistry and potentially impactful roles of unavoidable surface impurities.

Published

2019

20. Identifying the Role of Dynamic Surface Hydroxides in the Dehydrogenation of Ti-Doped NaAlH4.

Author

White, James L, Rowberg, Andrew JE, Wan, Liwen F, Kang, ShinYoung, Ogitsu, Tadashi, Kolasinski, Robert D, Whaley, Josh A, Baker, Alexander A, Lee, Jonathan RI, Liu, Yi-Sheng, Trotochaud, Lena, Guo, Jinghua, Stavila, Vitalie, Prendergast, David, Bluhm, Hendrik, Allendorf, Mark D, Wood, Brandon C, and El Gabaly, Farid

Subjects

ab initio simulation, ambient-pressure X-ray photoelectron spectroscopy, hydrogen storage, sodium aluminum hydride, surface chemistry, Chemical Sciences, Engineering, Nanoscience & Nanotechnology

Abstract

Solid-state metal hydrides are prime candidates to replace compressed hydrogen for fuel cell vehicles due to their high volumetric capacities. Sodium aluminum hydride has long been studied as an archetype for higher-capacity metal hydrides, with improved reversibility demonstrated through the addition of titanium catalysts; however, atomistic mechanisms for surface processes, including hydrogen desorption, are still uncertain. Here, operando and ex situ measurements from a suite of diagnostic tools probing multiple length scales are combined with ab initio simulations to provide a detailed and unbiased view of the evolution of the surface chemistry during hydrogen release. In contrast to some previously proposed mechanisms, the titanium dopant does not directly facilitate desorption at the surface. Instead, oxidized surface species, even on well-protected NaAlH4 samples, evolve during dehydrogenation to form surface hydroxides with differing levels of hydrogen saturation. Additionally, the presence of these oxidized species leads to considerably lower computed barriers for H2 formation compared to pristine hydride surfaces, suggesting that oxygen may actively participate in hydrogen release, rather than merely inhibiting diffusion as is commonly presumed. These results demonstrate how close experiment-theory feedback can elucidate mechanistic understanding of complex metal hydride chemistry and potentially impactful roles of unavoidable surface impurities.

Published

2019

21. An Efficient Algorithm for Automatic Structure Optimization in X-ray Standing-Wave Experiments

Author

Karslıoğlu, Osman, Gehlmann, Mathias, Müller, Juliane, Nemšák, Slavomír, Sethian, James A, Kaduwela, Ajith, Bluhm, Hendrik, and Fadley, Charles

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Condensed Matter Physics, SWOPT, YXRO, SO-I, Data analysis, Optimization, physics.comp-ph, cond-mat.mtrl-sci, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Condensed matter physics

Abstract

X-ray standing-wave photoemission experiments involving multilayered samples are emerging as unique probes of the buried interfaces that are ubiquitous in current device and materials research. Such data require for their analysis a structure optimization process comparing experiment to theory that is not straightforward. In this work, we present a new computer program for optimizing the analysis of standing-wave data, called SWOPT, that automates this trial-and-error optimization process. The program includes an algorithm that has been developed for computationally expensive problems: so-called black-box simulation optimizations. It also includes a more efficient version of the Yang X-ray Optics Program (YXRO) [Yang, S.-H., Gray, A.X., Kaiser, A.M., Mun, B.S., Sell, B.C., Kortright, J.B., Fadley, C.S., J. Appl. Phys. 113, 1 (2013)] which is about an order of magnitude faster than the original version. Human interaction is not required during optimization. We tested our optimization algorithm on real and hypothetical problems and show that it finds better solutions significantly faster than a random search approach. The total optimization time ranges, depending on the sample structure, from minutes to a few hours on a modern computer, and can be up to 100x faster than a corresponding manual optimization. These speeds make the SWOPT program a valuable tool for real-time analyses of data during synchrotron experiments.

Published

2019

22. Efficient charge generation from triplet excitons in metal-organic heterojunctions

Author

Roth, Friedrich, Neppl, Stefan, Shavorskiy, Andrey, Arion, Tiberiu, Mahl, Johannes, Seo, Hyun Ook, Bluhm, Hendrik, Hussain, Zahid, Gessner, Oliver, and Eberhardt, Wolfgang

Subjects

Engineering, Chemical Sciences, Nanotechnology, Chemical sciences, Physical sciences

Abstract

The success of many emerging molecular electronics concepts hinges on an atomistic understanding of the underlying electronic dynamics. We employ picosecond time-resolved x-ray photoemission spectroscopy (tr-XPS) to elucidate the roles of singlet and triplet excitons for photoinduced charge generation at a copper-phthalocyanine-C60 heterojunction. Contrary to common belief, fast intersystem crossing to triplet excitons after photoexcitation is not a loss channel but contributes to a significantly larger extent to the time-integrated interfacial charge generation than the initially excited singlet excitons. The tr-XPS data provide direct access to the diffusivity of the triplet excitons DCuPc=(1.8±1.2)×10-5cm2/s (where CuPc is copper-phthalocyanine) and their diffusion length Ldiff=(8±3)nm.

Published

2019

23. Enhancing Graphene Protective Coatings by Hydrogen-Induced Chemical Bond Formation

Author

Kyhl, Line, Balog, Richard, Cassidy, Andrew, Jørgensen, Jakob, Grubisic-Čabo, Antonija, Trotochaud, Lena, Bluhm, Hendrik, and Hornekær, Liv

Subjects

Biological Sciences, Macromolecular and Materials Chemistry, Chemical Sciences, Industrial Biotechnology, Engineering, Nanotechnology, Prevention, graphene, coatings, intercalation, interface, XPS, Industrial biotechnology, Macromolecular and materials chemistry

Abstract

Increased interactions at the graphene-metal interface are here demonstrated to yield an effective prevention of intercalation of foreign species below the graphene cover. Hereby, an engineering pathway for increasing the usability of graphene as a metal coating is demonstrated. Graphene on Ir(111) (Gr/Ir(111)) is used as a model system, as it has previously been well-established that an increased interaction and formation of chemical bonds at the graphene-Ir interface can be induced by hydrogen functionalization of the graphene from its top side. With X-ray photoelectron spectroscopy, it is shown that hydrogen-induced increased interactions at the Gr/Ir(111) interface effectively prevents intercalation of CO in the millibar range. The scheme leads to protection against at least 10 times higher pressure and 70 times higher fluences of CO, compared to the protection offered by pristine Gr/Ir(111).

Published

2018

24. Structure of Copper–Cobalt Surface Alloys in Equilibrium with Carbon Monoxide Gas

Author

Eren, Baran, Torres, Daniel, Karslıoğlu, Osman, Liu, Zongyuan, Wu, Cheng Hao, Stacchiola, Dario, Bluhm, Hendrik, Somorjai, Gabor A, and Salmeron, Miquel

Subjects

Chemical Sciences, Physical Chemistry, General Chemistry, Chemical sciences, Engineering

Abstract

We studied the structure of the copper-cobalt (CuCo) surface alloy, formed by Co deposition on Cu(110), in dynamic equilibrium with CO. Using scanning tunneling microscopy (STM), we found that, in vacuum at room temperature and at low Co coverage, clusters of a few Co atoms substituting Cu atoms form at the surface. At CO pressures in the Torr range, we found that up to 2.5 CO molecules can bind on a single Co atom, in carbonyl-like configurations. Based on high-resolution STM images, together with density functional theory calculations, we determined the most stable CuCo cluster structures formed with bound CO. Such carbonyl-like formation manifests in shifts in the binding energy of the Co core-level peaks in X-ray photoelectron spectra, as well as shifts in the vibrational modes of adsorbed CO in infrared reflection absorption spectra. The multiple CO adsorption on a Co site weakens the Co-CO bond and thus reduces the C-O bond scission probability. Our results may explain the different product distribution, including higher selectivity toward alcohol formation, when bimetallic CuCo catalysts are used compared to pure Co.

Published

2018

25. Structure of Copper-Cobalt Surface Alloys in Equilibrium with Carbon Monoxide Gas.

Author

Eren, Baran, Torres, Daniel, Karslıoğlu, Osman, Liu, Zongyuan, Wu, Cheng Hao, Stacchiola, Dario, Bluhm, Hendrik, Somorjai, Gabor A, and Salmeron, Miquel

Subjects

General Chemistry, Chemical Sciences

Abstract

We studied the structure of the copper-cobalt (CuCo) surface alloy, formed by Co deposition on Cu(110), in dynamic equilibrium with CO. Using scanning tunneling microscopy (STM), we found that, in vacuum at room temperature and at low Co coverage, clusters of a few Co atoms substituting Cu atoms form at the surface. At CO pressures in the Torr range, we found that up to 2.5 CO molecules can bind on a single Co atom, in carbonyl-like configurations. Based on high-resolution STM images, together with density functional theory calculations, we determined the most stable CuCo cluster structures formed with bound CO. Such carbonyl-like formation manifests in shifts in the binding energy of the Co core-level peaks in X-ray photoelectron spectra, as well as shifts in the vibrational modes of adsorbed CO in infrared reflection absorption spectra. The multiple CO adsorption on a Co site weakens the Co-CO bond and thus reduces the C-O bond scission probability. Our results may explain the different product distribution, including higher selectivity toward alcohol formation, when bimetallic CuCo catalysts are used compared to pure Co.

Published

2018

26. X-Ray Spectroscopic Characterization of BaO, Ba(OH)2, BaCO3, and Ba(NO3)2

Author

Karslıoğlu, Osman, Trotochaud, Lena, Zegkinoglou, Ioannis, and Bluhm, Hendrik

Subjects

Inorganic Chemistry, Chemical Sciences, NEXAFS, APXPS, barium oxide, barium hydroxide, barium carbonate, barium nitrate, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Condensed Matter Physics, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Condensed matter physics

Abstract

Simple inorganic barium compounds are difficult to study spectroscopically in the surface sensitive soft X-ray regime due to significant surface contamination that can dominate the spectra. Here we present a near-edge X-ray absorption (NEXAFS) and X-ray photoelectron spectroscopic (XPS) study of four barium compounds: BaO, Ba(OH)2, BaCO3, and Ba(NO3)2. Using an ambient-pressure XPS instrument we prepared thin film samples in situ, which provided a high degree of control over the surface chemistry and significantly reduced the amount of contamination. The O K-edge spectrum for BaO presented here is in excellent agreement with the latest calculations in the literature, and indicates that experimental spectra in the literature for this compound may have suffered from carbonate contamination.

Published

2018

27. Exciting H2 Molecules for Graphene Functionalization

Author

Kyhl, Line, Bisson, Régis, Balog, Richard, Groves, Michael N, Kolsbjerg, Esben Leonhard, Cassidy, Andrew Martin, Jørgensen, Jakob Holm, Halkjær, Susanne, Miwa, Jill A, Čabo, Antonija Grubišić, Angot, Thierry, Hofmann, Philip, Arman, Mohammad Alif, Urpelainen, Samuli, Lacovig, Paolo, Bignardi, Luca, Bluhm, Hendrik, Knudsen, Jan, Hammer, Bjørk, and Hornekaer, Liv

Subjects

Chemical Sciences, Physical Chemistry, Physical Sciences, Atomic, Molecular and Optical Physics, Condensed Matter Physics, Affordable and Clean Energy, graphene, vibrational excitation, nanostructured functionalization, band gap engineering molecular hydrogen, catalysis, band gap engineering, molecular hydrogen, Nanoscience & Nanotechnology

Abstract

Hydrogen functionalization of graphene by exposure to vibrationally excited H2 molecules is investigated by combined scanning tunneling microscopy, high-resolution electron energy loss spectroscopy, X-ray photoelectron spectroscopy measurements, and density functional theory calculations. The measurements reveal that vibrationally excited H2 molecules dissociatively adsorb on graphene on Ir(111) resulting in nanopatterned hydrogen functionalization structures. Calculations demonstrate that the presence of the Ir surface below the graphene lowers the H2 dissociative adsorption barrier and allows for the adsorption reaction at energies well below the dissociation threshold of the H-H bond. The first reacting H2 molecule must contain considerable vibrational energy to overcome the dissociative adsorption barrier. However, this initial adsorption further activates the surface resulting in reduced barriers for dissociative adsorption of subsequent H2 molecules. This enables functionalization by H2 molecules with lower vibrational energy, yielding an avalanche effect for the hydrogenation reaction. These results provide an example of a catalytically active graphene-coated surface and additionally set the stage for a re-interpretation of previous experimental work involving elevated H2 background gas pressures in the presence of hot filaments.

Published

2018

28. Water Adsorption and Dissociation on Polycrystalline Copper Oxides: Effects of Environmental Contamination and Experimental Protocol

Author

Trotochaud, Lena, Head, Ashley R, Pletincx, Sven, Karslıoǧlu, Osman, Yu, Yi, Waldner, Astrid, Kyhl, Line, Hauffman, Tom, Terryn, Herman, Eichhorn, Bryan, and Bluhm, Hendrik

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Engineering, Chemical sciences, Physical sciences

Abstract

We use ambient-pressure X-ray photoelectron spectroscopy (APXPS) to study chemical changes, including hydroxylation and water adsorption, at copper oxide surfaces from ultrahigh vacuum to ambient relative humidities of ∼5%. Polycrystalline CuO and Cu2O surfaces were prepared by selective oxidation of metallic copper foils. For both oxides, hydroxylation occurs readily, even at high-vacuum conditions. Hydroxylation on both oxides plateaus near ∼0.01% relative humidity (RH) at a coverage of ∼1 monolayer. In contrast to previous studies, neither oxide shows significant accumulation of molecular water; rather, both surfaces show a high affinity for adventitious carbon contaminants. Results of isobaric and isothermic experiments are compared, and the strengths and potential drawbacks of each method are discussed. We also provide critical evaluations of the effects of the hot filament of the ion pressure gauge on the reactivity of gas-phase species, the peak fitting procedure on the quantitative analysis of spectra, and rigorous accounting of carbon contamination on data analysis and interpretation. This work underscores the importance of considering experimental design and data analysis protocols during APXPS experiments with water vapor in order to minimize misinterpretations arising from these factors.

Published

2018

29. Water Adsorption and Dissociation on Polycrystalline Copper Oxides: Effects of Environmental Contamination and Experimental Protocol.

Author

Trotochaud, Lena, Head, Ashley R, Pletincx, Sven, Karslıoǧlu, Osman, Yu, Yi, Waldner, Astrid, Kyhl, Line, Hauffman, Tom, Terryn, Herman, Eichhorn, Bryan, and Bluhm, Hendrik

Subjects

Chemical Sciences, Engineering, Physical Sciences

Abstract

We use ambient-pressure X-ray photoelectron spectroscopy (APXPS) to study chemical changes, including hydroxylation and water adsorption, at copper oxide surfaces from ultrahigh vacuum to ambient relative humidities of ∼5%. Polycrystalline CuO and Cu2O surfaces were prepared by selective oxidation of metallic copper foils. For both oxides, hydroxylation occurs readily, even at high-vacuum conditions. Hydroxylation on both oxides plateaus near ∼0.01% relative humidity (RH) at a coverage of ∼1 monolayer. In contrast to previous studies, neither oxide shows significant accumulation of molecular water; rather, both surfaces show a high affinity for adventitious carbon contaminants. Results of isobaric and isothermic experiments are compared, and the strengths and potential drawbacks of each method are discussed. We also provide critical evaluations of the effects of the hot filament of the ion pressure gauge on the reactivity of gas-phase species, the peak fitting procedure on the quantitative analysis of spectra, and rigorous accounting of carbon contamination on data analysis and interpretation. This work underscores the importance of considering experimental design and data analysis protocols during APXPS experiments with water vapor in order to minimize misinterpretations arising from these factors.

Published

2018

30. Direct Mapping of Band Positions in Doped and Undoped Hematite during Photoelectrochemical Water Splitting

Author

Shavorskiy, Andrey, Ye, Xiaofei, Karslıoğlu, Osman, Poletayev, Andrey D, Hartl, Matthias, Zegkinoglou, Ioannis, Trotochaud, Lena, Nemšák, Slavomir, Schneider, Claus M, Crumlin, Ethan J, Axnanda, Stephanus, Liu, Zhi, Ross, Philip N, Chueh, William, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Chemistry, Affordable and Clean Energy, Climate Action, Physical Sciences, Chemical sciences, Physical sciences

Abstract

Photoelectrochemical water splitting is a promising pathway for the direct conversion of renewable solar energy to easy to store and use chemical energy. The performance of a photoelectrochemical device is determined in large part by the heterogeneous interface between the photoanode and the electrolyte, which we here characterize directly under operating conditions using interface-specific probes. Utilizing X-ray photoelectron spectroscopy as a noncontact probe of local electrical potentials, we demonstrate direct measurements of the band alignment at the semiconductor/electrolyte interface of an operating hematite/KOH photoelectrochemical cell as a function of solar illumination, applied potential, and doping. We provide evidence for the absence of in-gap states in this system, which is contrary to previous measurements using indirect methods, and give a comprehensive description of shifts in the band positions and limiting processes during the photoelectrochemical reaction.

Published

2017

31. Direct Mapping of Band Positions in Doped and Undoped Hematite during Photoelectrochemical Water Splitting.

Author

Shavorskiy, Andrey, Ye, Xiaofei, Karslıoğlu, Osman, Poletayev, Andrey D, Hartl, Matthias, Zegkinoglou, Ioannis, Trotochaud, Lena, Nemšák, Slavomir, Schneider, Claus M, Crumlin, Ethan J, Axnanda, Stephanus, Liu, Zhi, Ross, Philip N, Chueh, William, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Sciences

Abstract

Photoelectrochemical water splitting is a promising pathway for the direct conversion of renewable solar energy to easy to store and use chemical energy. The performance of a photoelectrochemical device is determined in large part by the heterogeneous interface between the photoanode and the electrolyte, which we here characterize directly under operating conditions using interface-specific probes. Utilizing X-ray photoelectron spectroscopy as a noncontact probe of local electrical potentials, we demonstrate direct measurements of the band alignment at the semiconductor/electrolyte interface of an operating hematite/KOH photoelectrochemical cell as a function of solar illumination, applied potential, and doping. We provide evidence for the absence of in-gap states in this system, which is contrary to previous measurements using indirect methods, and give a comprehensive description of shifts in the band positions and limiting processes during the photoelectrochemical reaction.

Published

2017

32. Combined soft and hard X-ray ambient pressure photoelectron spectroscopy studies of semiconductor/electrolyte interfaces

Author

Starr, David E, Favaro, Marco, Abdi, Fatwa F, Bluhm, Hendrik, Crumlin, Ethan J, and van de Krol, Roel

Subjects

Macromolecular and Materials Chemistry, Chemical Sciences, Physical Chemistry, Ambient pressure, Photoelectron spectroscopy, Solid liquid interface, HAXPES, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Condensed Matter Physics, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Condensed matter physics

Abstract

The development of solar fuel generating materials would greatly benefit from a molecular level understanding of the semiconductor/electrolyte interface and changes in the interface induced by an applied potential and illumination by solar light. Ambient pressure photoelectron spectroscopy techniques with both soft and hard X-rays, AP-XPS and AP-HAXPES respectively, have the potential to markedly contribute to this understanding. In this paper we initially provide two examples of current challenges in solar fuels material development that AP-XPS and AP-HAXPES can directly address. This will be followed by a brief description of the distinguishing and complementary characteristics of soft and hard X-ray AP-XPS and AP-HAXPES and best approaches to achieving monolayer sensitivity in solid/aqueous electrolyte studies. In particular we focus on the detection of surface adsorbed hydroxyl groups in the presence of aqueous hydroxide anions in the electrolyte, a common situation when investigating photoanodes for solar fuel generating applications. The paper concludes by providing an example of a combined AP-XPS and AP-HAXPES study of a semiconductor/aqueous electrolyte interface currently used in water splitting devices specifically the BiVO4/aqueous potassium phosphate electrolyte interface.

Published

2017

33. CO adsorption on Pd(100) studied by multimodal ambient pressure X-ray photoelectron and infrared reflection absorption spectroscopies

Author

Head, Ashley R, Karslıoǧlu, Osman, Gerber, Timm, Yu, Yi, Trotochaud, Lena, Raso, Joseph, Kerger, Philipp, and Bluhm, Hendrik

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Bridging CO, Atop CO, Surface coverage, IRRAS, APXPS, Condensed Matter Physics, Quantum Physics, Physical Chemistry (incl. Structural), Chemical Physics, Physical chemistry, Condensed matter physics, Quantum physics

Abstract

The adsorption of CO on Pd(100) was investigated using simultaneous ambient pressure X-ray photoelectron spectroscopy (APXPS) and infrared reflection absorption infrared spectroscopy (IRRAS). The measurements were performed as a function of CO partial pressures from ultra-high vacuum to 0.5 Torr. Total CO coverages estimated from the complementary APXPS and IRRAS measurements are in good agreement. A signal for atop CO, which is uncommon for Pd(100), was observed in the IRRAS data and was used to identify the C 1 s binding energy of this species. Discerning this binding configuration of CO on the Pd(100) surface at elevated pressures has significance for catalytic reactions involving CO, where bridging CO is often the only configuration considered. We also detail the combined APXPS/IRRAS instrumentation and discuss ways to improve these multimodal measurements, which should have wide applicability across many areas of surface and interface science.

Published

2017

34. Spectroscopic and Computational Investigation of Room-Temperature Decomposition of a Chemical Warfare Agent Simulant on Polycrystalline Cupric Oxide

Author

Trotochaud, Lena, Tsyshevsky, Roman, Holdren, Scott, Fears, Kenan, Head, Ashley R, Yu, Yi, Karslıoğlu, Osman, Pletincx, Sven, Eichhorn, Bryan, Owrutsky, Jeffrey, Long, Jeffrey, Zachariah, Michael, Kuklja, Maija M, and Bluhm, Hendrik

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Materials, Chemical sciences

Abstract

Certain organophosphorus molecules are infamous due to their use as highly toxic nerve agents. The filtration materials currently in common use for protection against chemical warfare agents were designed before organophosphorus compounds were used as chemical weapons. A better understanding of the surface chemistry between simulant molecules and the individual filtration-material components is a critical precursor to the development of more effective materials for filtration, destruction, decontamination, and/or sensing of nerve agents. Here, we report on the surface adsorption and reactions of a sarin simulant molecule, dimethyl methylphosphonate (DMMP), with cupric oxide surfaces. In situ ambient pressure X-ray photoelectron and infrared spectroscopies are coupled with density functional calculations to propose mechanisms for DMMP decomposition on CuO. We find extensive room temperature decomposition of DMMP on CuO, with the majority of decomposition fragments bound to the CuO surface. We observe breaking of PO-CH3, P-OCH3, and P-CH3 bonds at room temperature. On the basis of these results, we identify specific DMMP decomposition mechanisms not seen on other metal oxides. Participation of lattice oxygen in the decomposition mechanism leads to significant changes in chemical and electronic surface environment, which are manifest in the spectroscopic and computational data. This study establishes a computational baseline for the study of highly toxic organophosphorous compounds on metal oxide surfaces.

Published

2017

35. Spectroscopic and Computational Investigation of Room-Temperature Decomposition of a Chemical Warfare Agent Simulant on Polycrystalline Cupric Oxide

Author

Trotochaud, L, Tsyshevsky, R, Holdren, S, Fears, K, Head, AR, Yu, Y, Karslloǧlu, O, Pletincx, S, Eichhorn, B, Owrutsky, J, Long, J, Zachariah, M, Kuklja, MM, and Bluhm, H

Subjects

Materials, Chemical Sciences, Engineering

Abstract

Certain organophosphorus molecules are infamous due to their use as highly toxic nerve agents. The filtration materials currently in common use for protection against chemical warfare agents were designed before organophosphorus compounds were used as chemical weapons. A better understanding of the surface chemistry between simulant molecules and the individual filtration-material components is a critical precursor to the development of more effective materials for filtration, destruction, decontamination, and/or sensing of nerve agents. Here, we report on the surface adsorption and reactions of a sarin simulant molecule, dimethyl methylphosphonate (DMMP), with cupric oxide surfaces. In situ ambient pressure X-ray photoelectron and infrared spectroscopies are coupled with density functional calculations to propose mechanisms for DMMP decomposition on CuO. We find extensive room temperature decomposition of DMMP on CuO, with the majority of decomposition fragments bound to the CuO surface. We observe breaking of PO-CH3, P-OCH3, and P-CH3 bonds at room temperature. On the basis of these results, we identify specific DMMP decomposition mechanisms not seen on other metal oxides. Participation of lattice oxygen in the decomposition mechanism leads to significant changes in chemical and electronic surface environment, which are manifest in the spectroscopic and computational data. This study establishes a computational baseline for the study of highly toxic organophosphorous compounds on metal oxide surfaces.

Published

2017

36. Equilibrium oxygen storage capacity of ultrathin CeO2-δ depends non-monotonically on large biaxial strain

Author

Balaji Gopal, Chirranjeevi, García-Melchor, Max, Lee, Sang Chul, Shi, Yezhou, Shavorskiy, Andrey, Monti, Matteo, Guan, Zixuan, Sinclair, Robert, Bluhm, Hendrik, Vojvodic, Aleksandra, and Chueh, William C

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry

Abstract

Elastic strain is being increasingly employed to enhance the catalytic properties of mixed ion-electron conducting oxides. However, its effect on oxygen storage capacity is not well established. Here, we fabricate ultrathin, coherently strained films of CeO2-δ between 5.6% biaxial compression and 2.1% tension. In situ ambient pressure X-ray photoelectron spectroscopy reveals up to a fourfold enhancement in equilibrium oxygen storage capacity under both compression and tension. This non-monotonic variation with strain departs from the conventional wisdom based on a chemical expansion dominated behaviour. Through depth profiling, film thickness variations and a coupled photoemission-thermodynamic analysis of space-charge effects, we show that the enhanced reducibility is not dominated by interfacial effects. On the basis of ab initio calculations of oxygen vacancy formation incorporating defect interactions and vibrational contributions, we suggest that the non-monotonicity arises from the tetragonal distortion under large biaxial strain. These results may guide the rational engineering of multilayer and core-shell oxide nanomaterials.

Published

2017

37. Thermal desorption of dimethyl methylphosphonate from MoO3

Author

Head, Ashley R, Tang, Xin, Hicks, Zachary, Wang, Linjie, Bleuel, Hannes, Holdren, Scott, Trotochaud, Lena, Yu, Yi, Kyhl, Line, Karslıoǧlu, Osman, Fears, Kenan, Owrutsky, Jeffrey, Zachariah, Michael, Bowen, Kit H, and Bluhm, Hendrik

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Ambient pressure X-ray photoelectron spectroscopy, chemical warfare agent simulant, surface science, diffuse reflectance infrared Fourier transform spectroscopy, organophosphonate, temperature programmed desorption

Abstract

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 MoO3, 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 MoO3, 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 PCHx and POx decomposition products on the MoO3 surface. Heating under mTorr partial pressures of DMMP results in product accumulation.

Published

2017

38. Ambient-Pressure X‑ray Photoelectron Spectroscopy Study of Cobalt Foil Model Catalyst under CO, H2, and Their Mixtures

Author

Wu, Cheng Hao, Eren, Baran, Bluhm, Hendrik, and Salmeron, Miquel B

Subjects

Chemical Sciences, Physical Chemistry, catalysis, Fischer-Tropsch synthesis, cobalt, ambient-pressure X-ray photoelectron spectroscopy, Inorganic Chemistry, Organic Chemistry, Chemical Engineering, Industrial biotechnology, Organic chemistry, Physical chemistry

Abstract

Ambient-pressure X-ray photoelectron spectroscopy (XPS) was used to investigate the reactions of CO, H2, and their mixtures on Co foils. We found that CO adsorbs molecularly on the clean Co surface and desorbs intact in vacuum with increasing rate until ∼90°C where all CO desorbs in seconds. In equilibrium with 100 mTorr gas, CO dissociates above 120°C, leaving carbide species on the surface but no oxides, because CO efficiently reduces the oxides at temperatures ∼100°C lower than H2. Water as impurities or produced by reaction of CO and H2 efficiently oxidizes Co even at room temperature. Under 97:3 CO/H2 mixture and with increasing temperatures, the Co surface becomes more oxidized and covered by hydroxyl groups until ∼150°C where surface starts to get reduced, accompanied by carbide accumulation indicative of CO dissociation. A similar trend was observed for 9:1 and 1:1 mixtures, but surface reduction begins at higher temperatures. (Figure Presented).

Published

2017

39. In Situ Characterization of the Initial Effect of Water on Molecular Interactions at the Interface of Organic/Inorganic Hybrid Systems

Author

Pletincx, Sven, Trotochaud, Lena, Fockaert, Laura-Lynn, Mol, Johannes MC, Head, Ashley R, Karslıoğlu, Osman, Bluhm, Hendrik, Terryn, Herman, and Hauffman, Tom

Subjects

Engineering, Chemical Sciences, Physical Chemistry

Abstract

Probing initial interactions at the interface of hybrid systems under humid conditions has the potential to reveal the local chemical environment at solid/solid interfaces under real-world, technologically relevant conditions. Here, we show that ambient pressure X-ray photoelectron spectroscopy (APXPS) with a conventional X-ray source can be used to study the effects of water exposure on the interaction of a nanometer-thin polyacrylic acid (PAA) layer with a native aluminum oxide surface. The formation of a carboxylate ionic bond at the interface is characterized both with APXPS and in situ attenuated total reflectance Fourier transform infrared spectroscopy in the Kretschmann geometry (ATR-FTIR Kretschmann). When water is dosed in the APXPS chamber up to 5 Torr (~28% relative humidity), an increase in the amount of ionic bonds at the interface is observed. To confirm our APXPS interpretation, complementary ATR-FTIR Kretschmann experiments on a similar model system, which is exposed to an aqueous electrolyte, are conducted. These spectra demonstrate that water leads to an increased wet adhesion through increased ionic bond formation.

Published

2017

40. Unravelling the Chemical Influence of Water on the PMMA/Aluminum Oxide Hybrid Interface In Situ

Author

Pletincx, Sven, Marcoen, Kristof, Trotochaud, Lena, Fockaert, Laura-Lynn, Mol, Johannes MC, Head, Ashley R, Karslioğlu, Osman, Bluhm, Hendrik, Terryn, Herman, and Hauffman, Tom

Subjects

Engineering, Materials Engineering, Chemical Sciences, Physical Chemistry

Abstract

Understanding the stability of chemical interactions at the polymer/metal oxide interface under humid conditions is vital to understand the long-term durability of hybrid systems. Therefore, the interface of ultrathin PMMA films on native aluminum oxide, deposited by reactive adsorption, was studied. The characterization of the interface of the coated substrates was performed using ambient pressure X-ray photoelectron spectroscopy (APXPS), Fourier transform infrared spectroscopy in the Kretschmann geometry (ATR-FTIR Kretschmann) and time-of-flight secondary ion mass spectrometry (ToF-SIMS). The formation of hydrogen bonds and carboxylate ionic bonds at the interface are observed. The formed ionic bond is stable up to 5 Torr water vapour pressure as shown by APXPS. However, when the coated samples are exposed to an excess of aqueous electrolyte, an increase in the amount of carboxylate bonds at the interface, as a result of hydrolysis of the methoxy group, is observed by ATR-FTIR Kretschmann. These observations, supported by ToF-SIMS spectra, lead to the proposal of an adsorption mechanism of PMMA on aluminum oxide, which shows the formation of methanol at the interface and the effect of water molecules on the different interfacial interactions.

Published

2017

41. Adsorption of Dimethyl Methylphosphonate on MoO3: The Role of Oxygen Vacancies

Author

Head, Ashley R, Tsyshevsky, Roman, Trotochaud, Lena, Yu, Yi, Kyhl, Line, Karslıoǧlu, Osman, Kuklja, Maija M, and Bluhm, Hendrik

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Technology, Chemical sciences

Abstract

Dimethyl methylphosphonate (DMMP) is a common chemical warfare agent simulant and is widely used in adsorption studies. To further increase the understanding of DMMP interactions with metal oxides, ambient pressure X-ray photoelectron spectroscopy was used to study the adsorption of DMMP on MoO3, including the effects of oxygen vacancies, surface hydroxyl groups, and adsorbed molecular water. Density functional theory calculations were used to aid in the interpretation of the APXPS results. An inherent lack of Lewis acid metal sites results in weak interactions of DMMP with MoO3. Adsorption is enhanced by the presence of oxygen vacancies, hydroxyl groups, and molecular water on the MoO3 surface, as measured by photoelectron spectroscopy. Computational results agree with these findings and suggest the formation of methanol through several possible pathways, but all require a proton transferred from a hydroxyl group on the surface.

Published

2016

42. Adsorption of Dimethyl Methylphosphonate on MoO3: The Role of Oxygen Vacancies

Author

Head, AR, Tsyshevsky, R, Trotochaud, L, Yu, Y, Kyhl, L, Karslloǧlu, O, Kuklja, MM, and Bluhm, H

Subjects

Physical Chemistry, Engineering, Chemical Sciences, Technology

Abstract

Dimethyl methylphosphonate (DMMP) is a common chemical warfare agent simulant and is widely used in adsorption studies. To further increase the understanding of DMMP interactions with metal oxides, ambient pressure X-ray photoelectron spectroscopy was used to study the adsorption of DMMP on MoO3, including the effects of oxygen vacancies, surface hydroxyl groups, and adsorbed molecular water. Density functional theory calculations were used to aid in the interpretation of the APXPS results. An inherent lack of Lewis acid metal sites results in weak interactions of DMMP with MoO3. Adsorption is enhanced by the presence of oxygen vacancies, hydroxyl groups, and molecular water on the MoO3 surface, as measured by photoelectron spectroscopy. Computational results agree with these findings and suggest the formation of methanol through several possible pathways, but all require a proton transferred from a hydroxyl group on the surface.

Published

2016

43. The Active State of Supported Ruthenium Oxide Nanoparticles during Carbon Dioxide Methanation

Author

Carenco, Sophie, Sassoye, Capucine, Faustini, Marco, Eloy, Pierre, Debecker, Damien P, Bluhm, Hendrik, and Salmeron, Miquel

Subjects

Engineering, Chemical Sciences, Physical Chemistry, Technology, Chemical sciences

Abstract

Ruthenium catalysts supported on TiO2 have been shown to have competitive activity and selectivity for the methanation of CO2. In particular, a catalyst using preformed RuO2 nanoparticles deposited on a TiO2 support showed competitive performances in a previous study. In this work, ambient-pressure X-ray photoelectron spectroscopy was employed to determine the chemical state of this catalyst under reaction conditions. The active state of ruthenium was found to be the metallic one. Surface adsorbates were monitored in the steady state, and CHx species were found to be favored over adsorbed carbon monoxide at increasing temperatures.

Published

2016

44. The Active State of Supported Ruthenium Oxide Nanoparticles during Carbon Dioxide Methanation

Author

Carenco, S, Sassoye, C, Faustini, M, Eloy, P, Debecker, DP, Bluhm, H, and Salmeron, M

Subjects

Physical Chemistry, Engineering, Chemical Sciences, Technology

Abstract

Ruthenium catalysts supported on TiO2 have been shown to have competitive activity and selectivity for the methanation of CO2. In particular, a catalyst using preformed RuO2 nanoparticles deposited on a TiO2 support showed competitive performances in a previous study. In this work, ambient-pressure X-ray photoelectron spectroscopy was employed to determine the chemical state of this catalyst under reaction conditions. The active state of ruthenium was found to be the metallic one. Surface adsorbates were monitored in the steady state, and CHx species were found to be favored over adsorbed carbon monoxide at increasing temperatures.

Published

2016

45. Water at Interfaces

Author

Björneholm, Olle, Hansen, Martin H, Hodgson, Andrew, Liu, Li-Min, Limmer, David T, Michaelides, Angelos, Pedevilla, Philipp, Rossmeisl, Jan, Shen, Huaze, Tocci, Gabriele, Tyrode, Eric, Walz, Marie-Madeleine, Werner, Josephina, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Chemistry, General Chemistry, Chemical sciences, Engineering

Abstract

The interfaces of neat water and aqueous solutions play a prominent role in many technological processes and in the environment. Examples of aqueous interfaces are ultrathin water films that cover most hydrophilic surfaces under ambient relative humidities, the liquid/solid interface which drives many electrochemical reactions, and the liquid/vapor interface, which governs the uptake and release of trace gases by the oceans and cloud droplets. In this article we review some of the recent experimental and theoretical advances in our knowledge of the properties of aqueous interfaces and discuss open questions and gaps in our understanding.

Published

2016

46. Water at Interfaces.

Author

Björneholm, Olle, Hansen, Martin H, Hodgson, Andrew, Liu, Li-Min, Limmer, David T, Michaelides, Angelos, Pedevilla, Philipp, Rossmeisl, Jan, Shen, Huaze, Tocci, Gabriele, Tyrode, Eric, Walz, Marie-Madeleine, Werner, Josephina, and Bluhm, Hendrik

Subjects

General Chemistry, Chemical Sciences

Abstract

The interfaces of neat water and aqueous solutions play a prominent role in many technological processes and in the environment. Examples of aqueous interfaces are ultrathin water films that cover most hydrophilic surfaces under ambient relative humidities, the liquid/solid interface which drives many electrochemical reactions, and the liquid/vapor interface, which governs the uptake and release of trace gases by the oceans and cloud droplets. In this article we review some of the recent experimental and theoretical advances in our knowledge of the properties of aqueous interfaces and discuss open questions and gaps in our understanding.

Published

2016

47. Graphene Membranes for Atmospheric Pressure Photoelectron Spectroscopy

Author

Weatherup, Robert S, Eren, Baran, Hao, Yibo, Bluhm, Hendrik, and Salmeron, Miquel B

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, Atmospheric Pressure, Graphite, Particle Size, Photoelectron Spectroscopy, Surface Properties, Chemical sciences, Physical sciences

Abstract

Atmospheric pressure X-ray photoelectron spectroscopy (XPS) is demonstrated using single-layer graphene membranes as photoelectron-transparent barriers that sustain pressure differences in excess of 6 orders of magnitude. The graphene serves as a support for catalyst nanoparticles under atmospheric pressure reaction conditions (up to 1.5 bar), where XPS allows the oxidation state of Cu nanoparticles and gas phase species to be simultaneously probed. We thereby observe that the Cu(2+) oxidation state is stable in O2 (1 bar) but is spontaneously reduced under vacuum. We further demonstrate the detection of various gas-phase species (Ar, CO, CO2, N2, O2) in the pressure range 10-1500 mbar including species with low photoionization cross sections (He, H2). Pressure-dependent changes in the apparent binding energies of gas-phase species are observed, attributable to changes in work function of the metal-coated grids supporting the graphene. We expect atmospheric pressure XPS based on this graphene membrane approach to be a valuable tool for studying nanoparticle catalysis.

Published

2016

48. Graphene Membranes for Atmospheric Pressure Photoelectron Spectroscopy.

Author

Weatherup, Robert S, Eren, Baran, Hao, Yibo, Bluhm, Hendrik, and Salmeron, Miquel B

Subjects

Graphite, Atmospheric Pressure, Particle Size, Surface Properties, Photoelectron Spectroscopy, Physical Sciences, Chemical Sciences

Abstract

Atmospheric pressure X-ray photoelectron spectroscopy (XPS) is demonstrated using single-layer graphene membranes as photoelectron-transparent barriers that sustain pressure differences in excess of 6 orders of magnitude. The graphene serves as a support for catalyst nanoparticles under atmospheric pressure reaction conditions (up to 1.5 bar), where XPS allows the oxidation state of Cu nanoparticles and gas phase species to be simultaneously probed. We thereby observe that the Cu(2+) oxidation state is stable in O2 (1 bar) but is spontaneously reduced under vacuum. We further demonstrate the detection of various gas-phase species (Ar, CO, CO2, N2, O2) in the pressure range 10-1500 mbar including species with low photoionization cross sections (He, H2). Pressure-dependent changes in the apparent binding energies of gas-phase species are observed, attributable to changes in work function of the metal-coated grids supporting the graphene. We expect atmospheric pressure XPS based on this graphene membrane approach to be a valuable tool for studying nanoparticle catalysis.

Published

2016

49. Electron Spectroscopy and Computational Studies of Dimethyl Methylphosphonate.

Author

Head, Ashley R, Tsyshevsky, Roman, Trotochaud, Lena, Eichhorn, Bryan, Kuklja, Maija M, and Bluhm, Hendrik

Subjects

Chemical Sciences, Physical Chemistry, Theoretical and Computational Chemistry, Physical Sciences, Atomic, Molecular and Optical Physics, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Physical Chemistry (incl. Structural), Physical chemistry, Theoretical and computational chemistry, Atomic, molecular and optical physics

Abstract

Dimethyl methylphosphonate (DMMP) is one of the most widely used molecules to simulate chemical warfare agents in adsorption experiments. However, the details of the electronic structure of the isolated molecule have not yet been reported. We have directly probed the occupied valence and core levels using gas phase photoelectron spectroscopy and the unoccupied states using near-edge X-ray absorption fine structure (NEXAFS) spectroscopy. Density functional theory (DFT) calculations were used to study the electronic structure, assign the spectral features, and visualize the molecular orbitals. Comparison with parent molecules shows that valence and core-level binding energies of DMMP follow trends of functional group substitution on the P center. The photoelectron and NEXAFS spectra of the isolated molecule will serve as a reference in studies of DMMP adsorbed on surfaces.

Published

2016

50. Activation of Cu(111) surface by decomposition into nanoclusters driven by CO adsorption

Author

Eren, Baran, Zherebetskyy, Danylo, Patera, Laerte L, Wu, Cheng Hao, Bluhm, Hendrik, Africh, Cristina, Wang, Lin-Wang, Somorjai, Gabor A, and Salmeron, Miquel

Subjects

Physical Sciences, Chemical Sciences, Physical Chemistry, General Science & Technology

Abstract

The (111) surface of copper (Cu), its most compact and lowest energy surface, became unstable when exposed to carbon monoxide (CO) gas. Scanning tunneling microscopy revealed that at room temperature in the pressure range 0.1 to 100 Torr, the surface decomposed into clusters decorated by CO molecules attached to edge atoms. Between 0.2 and a few Torr CO, the clusters became mobile in the scale of minutes. Density functional theory showed that the energy gain from CO binding to low-coordinated Cu atoms and the weakening of binding of Cu to neighboring atoms help drive this process. Particularly for softer metals, the optimal balance of these two effects occurs near reaction conditions. Cluster formation activated the surface for water dissociation, an important step in the water-gas shift reaction.

Published

2016