Hard X-ray Microscopy with Elemental, Chemical and Structural Contrast

Schroer, Christian G.; Boye, Pit; Feldkamp, Jan M.; Patommel, Jens; Schropp, Andreas; Samberg, D.; Stephan, Sandra; Burghammer, Manfred; Schöder, Sébastian; Lengeler, B.; Falkenberg, Gerald; Wellenreuther, Gerd; Kuhlmann, Marion; Frahm, R.; Lützenkirchen‐Hecht, Dirk; Schroeder, Walter H.

doi:10.12693/aphyspola.117.357

Cited by 13 publications

(8 citation statements)

References 115 publications

(129 reference statements)

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“…This technique has not been applied to catalysis yet, but quantitative high‐resolution high‐contrast images of a microchip87 and of an ensemble of 30–50 nm gold particles on a silicon nitride membrane have been studied successfully using X‐rays (Figure 12, ref. 88). In addition, 2‐5 nm particles have recently been studied using 30 keV electrons in an SEM,89 demonstrating the potential of this technique.…”

Section: Towards Spatial Information On the Meso‐ To The Micro‐scalementioning

confidence: 99%

“…The spatial resolution of ptychographic imaging using X‐rays is presently a few tens of nm, limited primarily by the mechanical stability of the X‐ray microscope and by aspects of data acquisition and interpretation. Although only a few experiments have been performed so far,3e, 88, 90 in principle all coherent diffraction imaging techniques can be combined with X‐ray absorption spectroscopy.…”

Section: Towards Spatial Information On the Meso‐ To The Micro‐scalementioning

confidence: 99%

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Imaging Catalysts at Work: A Hierarchical Approach from the Macro‐ to the Meso‐ and Nano‐scale

2012

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This review highlights the importance of developing multi‐scale characterisation techniques for analysing operating catalysts in their working environment. We emphasise that a hierarchy of in situ techniques that provides macro‐, meso‐ and nano‐scale information is required to elucidate and optimise catalyst performance fully. This combined methodology should ideally embrace spatially resolved and spatio‐temporal monitoring of a) the structure, catalytic activity, temperature and heat/mass transfer pattern in axial and radial directions in real reactors, b) the structure and temperature/heat/mass transport gradients in shaped catalysts and catalyst grains and c) meso‐ and nano‐scale information about particles and clusters, whose physical and electronic properties are linked directly to the micro‐kinetic behaviour of the catalysts. Techniques such as X‐ray diffraction (XRD), infrared (IR), Raman, X‐ray photoelectron spectroscopy (XPS), UV/Vis, and X‐ray absorption spectroscopy (XAS), which have mainly provided global atomic scale information, are being developed to provide the same information on a more local scale, often with sub‐second time resolution. X‐ray microscopy, both in the soft and more recently in the hard X‐ray regime, allows two‐ and three‐dimensional information to be collected down to 10 nm spatial resolution in a gas atmosphere or liquid, although this improvement is at the expense of temporal resolution. Electron microscopy, which provides excellent local atomic scale structural and spectroscopic information, is being developed towards tomographic imaging and realistic conditions, allowing gaps to be bridged in pressure, reaction conditions and length scales, up to the meso‐ and macro‐scale. In addition, new techniques such as single molecule fluorescence spectroscopy and non‐linear spectroscopic techniques are emerging. In this review, we discuss prospects for the development and combined application of both existing and new techniques for in situ catalyst characterisation.

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Section: Towards Spatial Information On the Meso‐ To The Micro‐scalementioning

confidence: 99%

Section: Towards Spatial Information On the Meso‐ To The Micro‐scalementioning

confidence: 99%

Imaging Catalysts at Work: A Hierarchical Approach from the Macro‐ to the Meso‐ and Nano‐scale

2012

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“…2 as strong excitations for potential applications. The low-lying M1 excitation can be employed via Nuclear Resonance Fluorescence (NRF) using focusing lenses for tomography and microscopy with µm resolution [11]. In Fig.…”

Section: Applicationsmentioning

confidence: 99%

Nuclear photonics

Habs¹,

Guenther²,

Jentschel³

et al. 2012

AIP Conference Proceedings

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With the planned new γ-beam facilities like MEGa-ray at LLNL (USA) or ELI-NP at Bucharest (Romania) with 10 13 γ/s and a band width of ΔE γ /E γ ≈ 10 −3 , a new era of γ beams with energies up to 20 MeV comes into operation, compared to the present world-leading HIγS facility at Duke University (USA) with 10 8 γ/s and ΔE γ /E γ ≈ 3 · 10 −2 . In the long run even a seeded quantum FEL for γ beams may become possible, with much higher brilliance and spectral flux. At the same time new exciting possibilities open up for focused γ beams. Here we describe a new experiment at the γ beam of the ILL reactor (Grenoble, France), where we observed for the first time that the index of refraction for γ beams is determined by virtual pair creation. Using a combination of refractive and reflective optics, efficient monochromators for γ beams are being developed. Thus, we have to optimize the total system: the γ-beam facility, the γ-beam optics and γ detectors. We can trade γ intensity for band width, going down to ΔE γ /E γ ≈ 10 −6 and address individual nuclear levels. The term "nuclear photonics" stresses the importance of nuclear applications. We can address with γ-beams individual nuclear isotopes and not just elements like with X-ray beams. Compared to X rays, γ beams can penetrate much deeper into big samples like radioactive waste barrels, motors or batteries. We can perform tomography and microscopy studies by focusing down to μm resolution using Nuclear Resonance Fluorescence (NRF) for detection with eV resolution and high spatial resolution at the same time. We discuss the dominating M1 and E1 excitations like the scissors mode, two-phonon quadrupole octupole excitations, pygmy dipole excitations or giant dipole excitations under the new facet of applications. We find many new applications in biomedicine, green energy, radioactive waste management or homeland security. Also more brilliant secondary beams of neutrons and positrons can be produced.

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“…Although the spatial resolution with hard X-rays is limited, they offer a higher penetration depth and allow imaging under more realistic reaction conditions (de Smit et al, 2008; de Groot et al, 2010; Falcone et al, 2011; Cats et al, 2013) and thus the complementary use of these electron and X-ray microscopy techniques is beneficial (Thomas & Hernandez-Garrido, 2009; Li et al, 2015 b ; Stach et al, 2015). In particular, hard X-ray ptychography (Schroer et al, 2010; Høydalsvik et al, 2014) as a high-resolution X-ray microscopy technique has reached spatial resolutions below 10 nm (Vila-Comamala et al, 2011; Schropp et al, 2012) and is thus attractive for in situ studies (Baier et al, 2016 a ). In addition, the application of resonant X-ray ptychography offers chemical contrast (Beckers et al, 2011; Hoppe et al, 2013), and if the coherent small-angle X-ray scattering (SAXS) contribution is analyzed, further information on nanostructured materials can be obtained, for example from in situ anomalous SAXS (Andreasen et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

Stability of a Bifunctional Cu-Based Core@Zeolite Shell Catalyst for Dimethyl Ether Synthesis Under Redox Conditions Studied by Environmental Transmission Electron Microscopy andIn SituX-Ray Ptychography

et al. 2017

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When using bifunctional core@shell catalysts, the stability of both the shell and core-shell interface is crucial for catalytic applications. In the present study, we elucidate the stability of a CuO/ZnO/Al2O3@ZSM-5 core@shell material, used for one-stage synthesis of dimethyl ether from synthesis gas. The catalyst stability was studied in a hierarchical manner by complementary environmental transmission electron microscopy (ETEM), scanning electron microscopy (SEM) and in situ hard X-ray ptychography with a specially designed in situ cell. Both reductive activation and reoxidation were applied. The core-shell interface was found to be stable during reducing and oxidizing treatment at 250°C as observed by ETEM and in situ X-ray ptychography, although strong changes occurred in the core on a 10 nm scale due to the reduction of copper oxide to metallic copper particles. At 350°C, in situ X-ray ptychography indicated the occurrence of structural changes also on the µm scale, i.e. the core material and parts of the shell undergo restructuring. Nevertheless, the crucial core-shell interface required for full bifunctionality appeared to remain stable. This study demonstrates the potential of these correlative in situ microscopy techniques for hierarchically designed catalysts.

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Hard X-ray Microscopy with Elemental, Chemical and Structural Contrast

Cited by 13 publications

References 115 publications

Imaging Catalysts at Work: A Hierarchical Approach from the Macro‐ to the Meso‐ and Nano‐scale

Imaging Catalysts at Work: A Hierarchical Approach from the Macro‐ to the Meso‐ and Nano‐scale

Nuclear photonics

Stability of a Bifunctional Cu-Based Core@Zeolite Shell Catalyst for Dimethyl Ether Synthesis Under Redox Conditions Studied by Environmental Transmission Electron Microscopy andIn SituX-Ray Ptychography

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