Philipp Bolz scite author profile

Philipp Bolz

4Publications

17Citation Statements Received

99Citation Statements Given

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Affiliations

GSI Helmholtz Centre for Heavy Ion Research, Technical University of Darmstadt

Publications

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Dynamic Response of Advanced Materials Impacted by Particle Beams: The MultiMat Experiment

Pasquali

Bertarelli

Accettura

et al. 2019

J. dynamic behavior mater.

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The introduction at CERN of new extremely energetic particle accelerators, such as the high-luminosity large hadron collider (HL-LHC) or the proposed future circular collider (FCC), will increase the energy stored in the circulating particle beams by almost a factor of two (from 360 to 680 MJ) and of more than 20 (up to 8500 MJ), respectively. In this scenario, it is paramount to assess the dynamic thermomechanical response of materials presently used, or being developed for future use, in beam intercepting devices (such as collimators, targets, dumps, absorbers, spoilers, windows, etc.) exposed to potentially destructive events caused by the impact of energetic particle beams. For this reason, a new HiRadMat experiment, named "MultiMat", was carried out in October 2017, with the goal of assessing the behaviour of samples exposed to high-intensity, high-energy proton pulses, made of a broad range of materials relevant for collimators and beam intercepting devices, thinfilm coatings and advanced equipment. This paper describes the experiment and its main results, collected online thanks to an extensive acquisition system and after the irradiation by non-destructive examination, as well as the numerical simulations performed to benchmark experimental data and extend materials constitutive models. Keywords Dynamic material behaviour • Thermomechanical stresses • Carbon-based and copper composites • Molybdenum and tungsten alloys • Particle beam impacts • Quasi-instantaneous heat deposition * M.

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Dynamic Radiation Effects Induced by Short‐Pulsed GeV U‐Ion Beams in Graphite and h‐BN Targets

Bolz

Drechsel

Prosvetov

et al. 2021

Shock and Vibration

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Targets of isotropic graphite and hexagonal boron nitride were exposed to short pulses of uranium ions with ∼1 GeV kinetic energy. The deposited power density of ∼3 MW/cm³ generates thermal stress in the samples leading to pressure waves. The velocity of the respective motion of the target surface was measured by laser Doppler vibrometry. The bending modes are identified as the dominant components in the velocity signal recorded as a function of time. With accumulated radiation damage, the bending mode frequency shifts towards higher values. Based on this shift, Young’s modulus of irradiated isotropic graphite is determined by comparison with ANSYS simulations. The increase of Young’s modulus up to 3 times the pristine value for the highest accumulated fluence of 3 × 1013 ions/cm2 is attributed to the beam-induced microstructural evolution into a disordered structure similar to glassy carbon. Young’s modulus values deduced from microindentation measurements are similar, confirming the validity of the method. Beam-induced stress waves remain in the elastic regime, and no large-scale damage can be observed in graphite. Hexagonal boron nitride shows lower radiation resistance. Circular cracks are generated already at low fluences, risking material failure when applied in high-dose environment.

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Dynamic Testing and Characterization of Advanced Materials in a New Experiment at CERN HiRadMat Facility

Bertarelli

Accettura

Berthomé

et al. 2018

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Dynamic Response of Graphitic Targets with Tantalum Cores Impacted by Pulsed 440‐GeV Proton Beams

Simon

Drechsel

Katrík

et al. 2021

Shock and Vibration

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Various graphite targets with a tantalum core were exposed to 440 GeV pulsed proton beams at the HiRadMat facility at CERN. The dynamic response was investigated by monitoring the surface velocity of the samples by laser Doppler vibrometry. The study comprises different graphite grades, such as polycrystalline, expanded and carbon-fiber reinforced graphite, and low-density graphitic foams, all candidates for beam-intercepting devices in high-power accelerators. The purpose of the tantalum core is to concentrate the large energy deposition in this high-density material that withstands the localized beam-induced temperature spike. The generated pressure waves are estimated to result in stresses of several hundred MPa which subsequently couple with the surrounding graphite materials where they are damped. Spatial energy deposition profiles were obtained by the Monte Carlo code FLUKA and the dynamic response was modelled using the implicit code ANSYS. Using advanced post-processing techniques, such as fast Fourier transformation and continuous wavelet transformation, different pressure wave components are identified and their contribution to the overall dynamic response of a two-body target and their failure mode are discussed. We show that selected low-intensity beam impacts can be simulated using straight-forward transient coupled thermal/structural implicit simulations. Carbon-fiber reinforced graphites exhibit large (macroscopic) mechanical strength, while their low-strength graphite matrix is identified as a potential source of failure. The dynamic response of low-density graphitic foams is surprisingly favourable, indicating promising properties for the application as high-power beam dump material.

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Philipp Bolz

Dynamic Response of Advanced Materials Impacted by Particle Beams: The MultiMat Experiment

Dynamic Radiation Effects Induced by Short‐Pulsed GeV U‐Ion Beams in Graphite and h‐BN Targets

Dynamic Testing and Characterization of Advanced Materials in a New Experiment at CERN HiRadMat Facility

Dynamic Response of Graphitic Targets with Tantalum Cores Impacted by Pulsed 440‐GeV Proton Beams

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