Comprehensive Study and Optimized Redesign of the CERN's Antiproton Decelerator Target

Torregrosa-Martin, C.; Leopoldo, Claudio

doi:10.4995/thesis/10251/100489

Cited by 3 publications

(10 citation statements)

References 99 publications

(150 reference statements)

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“…Within these activities, a set of new antiproton targets is being designed and manufactured. For arriving to such new design, several R&D activities were launched over the last years, particularly focused in understanding the mechanical response of the target core when subjected to the extreme dynamic stresses induced by the fast and high deposition of energy due to every proton beam impact . These activities are summarized in Section of this paper.…”

Section: Introductionmentioning

confidence: 74%

“…This response subjects the core material to compressive‐to‐tensile pressures of several gigapascals, above its strength. The simulations also suggest that the containing graphite matrix could be damaged by the generated stress wave propagating from the core . These results encouraged the execution of experimental studies (HiRadMat‐27 and HiRadMat‐42 experiments) aiming at validating these simulations and finding a core and matrix material configuration that could withstand these operating conditions.…”

Section: Previous Studies Leading To the Protad Designmentioning

confidence: 99%

“…This is attributed to its considerably higher ductility. In addition, the performed hydrocode simulations of Torregrosa et al were validated . Nevertheless, this experiment did not assess the response of Ta when subjected to a high number of proton beam impacts, nor the response of the graphite matrix.…”

Section: Previous Studies Leading To the Protad Designmentioning

confidence: 99%

“…For arriving to such new design, several R&D activities were launched over the last years, particularly focused in understanding the mechanical response of the target core when subjected to the extreme dynamic stresses induced by the fast and high deposition of energy due to every proton beam impact. 3 These activities are summarized in Section 2 of this paper. The results of such studies lead to the manufacturing of six target prototypes (PROTAD targets), which were tested under proton beam impacts using the CERN's HiRadMat facility.…”

Section: Introductionmentioning

confidence: 99%

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First prototypes of the new design of the CERN's antiproton production target

Torregrosa-Martin

Calviani

Solieri

et al. 2019

Mat Design Process Comm

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For antiproton production at CERN, high‐energy (26 GeV/c), intense, and short proton beams are impacted into a small rod—target core—made of a dense metal. Temperature rises in the order of 2000°C, and subsequent dynamic stresses of several gigapascals are induced in this rod every time it is impacted by the primary proton beam. Several R&D activities have been launched with the goal of proposing and manufacturing a new design of such device (named AD‐Target). A summary of these activities is presented, including the last design stage, which involves the manufacturing and testing of six real‐scale prototypes of the new target design. These prototypes (named PROTAD) consist of air‐cooled Ti‐6Al‐4V assemblies filled by matrices made of isostatic graphite or expanded graphite (EG), containing target cores made of small rods with different diameters (from 2 to 10 mm) of multiple grades of Ta, Ta2.5W, and Ir.

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Section: Introductionmentioning

confidence: 74%

Section: Previous Studies Leading To the Protad Designmentioning

confidence: 99%

Section: Previous Studies Leading To the Protad Designmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

First prototypes of the new design of the CERN's antiproton production target

Torregrosa-Martin

Calviani

Solieri

et al. 2019

Mat Design Process Comm

View full text Add to dashboard Cite

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“…Antiproton production requires the use of a very high density metal as target material and a very focused and intense primary proton beam impacting onto it. This leads to a huge and fast energy deposition in the bulk of target material, with its subsequent sudden increase of temperature and appearance of violent stress waves, which can eventually fracture it [15]. This phenomena has been extensively studied both numerically [16] and experimentally [17,18].…”

Section: Experimental Samplesmentioning

confidence: 99%

Development of a Neutron Imaging Station at the n_TOF Facility of CERN and Applications to Beam Intercepting Devices

et al. 2019

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A neutron radiography testing station has been developed exploiting the neutron beam of CERN's n_TOF Experimental Area 2, located at the shortest distance to the neutron producing-target. The characteristics of the n_TOF neutron beam for the imaging setup are presented in this paper, together with the obtained experimental results. The possible developments of neutron imaging capabilities of the n_TOF facility in terms of detection-systems and beam-line upgrades are as well outlined.

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Scaled prototype of a tantalum target embedded in expanded graphite for antiproton production: Design, manufacturing, and testing under proton beam impacts

Martin

Perillo‐Marcone

Grec

et al. 2018

Phys. Rev. Accel. Beams

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This study presents a further step within the ongoing R&D activities for the redesign of the CERN's Antiproton Decelerator Production Target (AD-Target). A first scaled target prototype, constituted of a sliced core made of ten Ta rods −8 mm diameter, 16 mm length-embedded in a compressed expanded graphite (EG) matrix, inserted in a 44 mm diameter Ti-6Al-4V container, has been built and tested under proton beam impacts at the CERN's HiRadMat facility, in the so called HRMT-42 experiment. This prototype has been designed following the lessons learned from previous numerical and experimental works (HRMT-27 experiment) aiming at answering the open questions left in these studies. Velocity data recorded on-line at the target periphery during the HRMT-42 experiment is presented, showing features of its dynamic response to proton beam impacts. Furthermore, x-ray and neutron tomographies of the target prototype after irradiation have been performed. These non-destructive techniques show the extensive plastic deformation of the Ta core, but suggest that the EG matrix can adapt to such deformation, which is a positive result. The neutron tomography successfully revealed the internal state of the tantalum core, showing the appearance of voids of several hundreds of micrometers, in particular in the downstream rods of the core. The possible origin of such voids is discussed while future microstructure analysis after the target opening will try to clarify their nature.

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Comprehensive Study and Optimized Redesign of the CERN's Antiproton Decelerator Target

Cited by 3 publications

References 99 publications

First prototypes of the new design of the CERN's antiproton production target

First prototypes of the new design of the CERN's antiproton production target

Development of a Neutron Imaging Station at the n_TOF Facility of CERN and Applications to Beam Intercepting Devices

Scaled prototype of a tantalum target embedded in expanded graphite for antiproton production: Design, manufacturing, and testing under proton beam impacts

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