Your search keyword '"Boillat, Pierre"' showing total 7 results

1. Event-based high-resolution neutron image formation analysis using intensified CMOS cameras.

Author

Gustschin, Alex, Han, Yiyong, Losko, Adrian, Wolfertz, Alexander, Hussey, Daniel S., Szentmiklósi, László, Kis, Zoltán, Trtik, Pavel, Boillat, Pierre, Kaestner, Anders, Strobl, Markus, Tengattini, Alessandro, Helfen, Lukas, and Schulz, Michael

Abstract

We present a versatile optical setup for high-resolution neutron imaging with an adaptable field of view and magnification that can resolve individual neutron absorption events with an image intensifier and a CMOS camera. Its imaging performance is characterized by evaluating the resolution limits of the individual optical components and resulting design aspects are discussed. Neutron radiography measurements of a Siemens star pattern were performed in event mode acquisition comparing two common high-resolution neutron scintillators, crystalline Gadolinium Gallium Garnet (GGG) and powdered Gadolinium Oxysulfide (GOS). An analysis of the light signature caused by neutron absorption events is performed and some resulting issues for both GGG and GOS regarding optical system design are addressed. Both scintillators reach similar resolution (4–5 μ m) in event mode acquisition despite different light emission characteristics. The findings suggest that, in the case of GOS, the resolution is limited by the size of the light clusters which in turn originate from the photon scattering at the boundaries of the powder particles comprising it, while with GGG the lower light conversion efficiency makes it challenging to collect enough photons to trigger sufficient signal amplification in the image intensifier. Overall, the proposed event-based evaluation of scintillators allows for quantifying and optimizing various design parameters, which is much more complex than adopting conventional methods based on integrated images. [ABSTRACT FROM AUTHOR]

Published

2024

2. Activated carbon cloth electrodes for capacitive deionization: a neutron imaging study.

Author

Butcher, Tim A., Prendeville, Lucy, Rafferty, Aran, Trtik, Pavel, Boillat, Pierre, and Coey, J. M. D.

Abstract

Neutron imaging was employed to track the uptake of Gd 3 + ions by the sub 2 nm micropores of charged activated carbon cloth electrodes from an aqueous Gd(NO 3 ) 3 solution. The transmitted neutron intensity evinces the persistent presence of Gd 3 + in the micropores during the discharge cycle, which is caused by the adsorption of oppositely charged ions. The charge efficiency of the activated carbon cloth system was determined by direct comparison with the imaged Gd 3 + concentration changes, with which the influence of ion swapping and resistive losses on capacitive deionization cells can be ascertained. [ABSTRACT FROM AUTHOR]

Published

2024

3. Absorption of pressurized methane in normal and supercooled p-xylene revealed via high-resolution neutron imaging.

Author

Vopička, Ondřej, Durďáková, Tereza-Markéta, Číhal, Petr, Boillat, Pierre, and Trtik, Pavel

Subjects

SUPERCOOLED liquids, LIQUEFIED natural gas, P-Xylene, MOLECULAR volume, METHANE, SURFACE tension, ATMOSPHERIC methane

Abstract

Supercooling of liquids leads to peculiarities which are scarcely studied under high-pressure conditions. Here, we report the surface tension, solubility, diffusivity, and partial molar volume for normal and supercooled liquid solutions of methane with p-xylene. Liquid bodies of perdeuterated p-xylene (p-C8D10), and, for comparison, o-xylene (o-C8D10), were exposed to pressurized methane (CH4, up to 101 bar) at temperatures ranging 7.0–30.0 °C and observed at high spatial resolution (pixel size 20.3 μm) using a non-tactile neutron imaging method. Supercooling led to the increase of diffusivity and partial molar volume of methane. Solubility and surface tension were insensitive to supercooling, the latter substantially depended on methane pressure. Overall, neutron imaging enabled to reveal and quantify multiple phenomena occurring in supercooled liquid p-xylene solutions of methane under pressures relevant to the freeze-out in the production of liquefied natural gas. [ABSTRACT FROM AUTHOR]

Published

2023

4. Cluster analysis: Application to sector indices and empirical validation.

Author

Boillat, Pierre-Yves, Skowronski, Nicolas, and Tuchschmid, Nils

Published

2002

5. Frame overlap Bragg edge imaging.

Author

Busi, Matteo, Čapek, Jan, Polatidis, Efthymios, Hovind, Jan, Boillat, Pierre, Tremsin, Anton S., Kockelmann, Winfried, and Strobl, Markus

Subjects

NEUTRONS spectra, NEUTRON source spectra, BRAGG raft, BRAGG'S law (Physics), WAVELENGTHS, THERMAL neutron beams, SIGNAL processing

Abstract

Neutron Bragg edge imaging enables spatially resolved studies of crystalline features through the exploitation and analysis of Bragg edges in the transmission spectra recorded in each pixel of an imaging detector. Studies with high spectral resolutions, as is required e.g. for high-resolution strain mapping, and with large wavelength ranges have been largely reserved to pulsed neutron sources. This is due to the fact, that the efficiency for high wavelength resolution measurements is significantly higher at short pulse sources. At continuous sources a large fraction of the available neutrons must be sacrificed in order to achieve high wavelength resolution for a relevant bandwidth e.g. through a chopper system. Here we introduce a pulse overlap transmission imaging technique, which is suited to increase the available flux of high wavelength resolution time-of-flight neutron Bragg edge imaging at continuous neutron sources about an order of magnitude. Proof-of-principle measurements utilizing a chopper with a fourfold repeated random slit distribution of eight slits were performed at a thermal neutron beamline. It is demonstrated, that disentanglement of the overlapping pulses is achieved with the correlation theorem for signal processing. Thus, the Bragg edge pattern can be reconstructed from the strongly overlapping Bragg edge spectra recorded and the results demonstrate the feasibility of the technique. [ABSTRACT FROM AUTHOR]

Published

2020

6. Visualization of supercritical water pseudo-boiling at Widom line crossover.

Author

Maxim, Florentina, Contescu, Cristian, Boillat, Pierre, Niceno, Bojan, Karalis, Konstantinos, Testino, Andrea, and Ludwig, Christian

Subjects

SUPERCRITICAL fluids, SUPERCRITICAL water, NUCLEAR engineering, WASTE treatment, VISUALIZATION, WATER use

Abstract

Supercritical water is a green solvent used in many technological applications including materials synthesis, nuclear engineering, bioenergy, or waste treatment and it occurs in nature. Despite its relevance in natural systems and technical applications, the supercritical state of water is still not well understood. Recent theories predict that liquid-like (LL) and gas-like (GL) supercritical water are metastable phases, and that the so-called Widom line zone is marking the crossover between LL and GL behavior of water. With neutron imaging techniques, we succeed to monitor density fluctuations of supercritical water while the system evolves rapidly from LL to GL as the Widom line is crossed during isobaric heating. Our observations show that the Widom line of water can be identified experimentally and they are in agreement with the current theory of supercritical fluid pseudo-boiling. This fundamental understanding allows optimizing and developing new technologies using supercritical water as a solvent. Supercritical water exists in gas- and liquid-like forms, but these have not been distinguished yet at the macroscale. Here the authors investigate supercritical water interacting with microporous carbon by neutron imaging, and observe the coexistence of gas- and liquid-like states upon crossing the Widom line. [ABSTRACT FROM AUTHOR]

Published

2019

7. Visualization and quantification of inhomogeneous and anisotropic magnetic fields by polarized neutron grating interferometry.

Author

Valsecchi, Jacopo, Harti, Ralph P., Raventós, Marc, Siegwart, Muriel D., Morgano, Manuel, Boillat, Pierre, Strobl, Markus, Hautle, Patrick, Holitzner, Lothar, Filges, Uwe, Treimer, Wolfgang, Piegsa, Florian M., and Grünzweig, Christian

Subjects

MAGNETIC fields, MAGNETIC field measurements, INTERFEROMETRY, NEUTRON beams, MAGNETIC moments, SMALL-angle neutron scattering

Abstract

The intrinsic magnetic moment of a neutron, combined with its charge neutrality, is a unique property which allows the investigation of magnetic phenomena in matter. Here we present how the utilization of a cold polarized neutron beam in neutron grating interferometry enables the visualization and characterization of magnetic properties on a microscopic scale in macroscopic samples. The measured signal originates from the phase shift induced by the magnetic potential. Our method enables the detection of previously inaccessible magnetic field gradients, in the order of T cm−1, extending the probed range by an order of magnitude. We visualize and quantify the phase shift induced by a well-defined square shaped uniaxial magnetic field and validate our experimental findings with theoretical calculations based on Hall probe measurements of the magnetic field distribution. This allows us to further extend our studies to investigations of inhomogeneous and anisotropic magnetic field distribution. The magnetic field imaging on microscopic scale is of great importance to fundamental research as well industrial applications. Here the authors show the capability to visualize and characterize the magnetic properties with 100-micrometer resolution in macroscopic samples using a cold polarized neutron beam in neutron grating interferometry. [ABSTRACT FROM AUTHOR]

Published

2019