Paolo Gradassi scite author profile

Modern hadron machines with high beam intensity may suffer from material damage in the case of large beam losses and even beam-intercepting devices, such as collimators, can be harmed. A systematic method to evaluate thresholds of damage owing to the impact of high energy particles is therefore crucial for safe operation and for predicting possible limitations in the overall machine performance. For this, a three-step simulation approach is presented, based on tracking simulations followed by calculations of energy deposited in the impacted material and hydrodynamic simulations to predict the thermomechanical effect of the impact. This approach is applied to metallic collimators at the CERN Large Hadron Collider (LHC), which in standard operation intercept halo protons, but risk to be damaged in the case of extraction kicker malfunction. In particular, tertiary collimators protect the aperture bottlenecks, their settings constrain the reach in β Ã and hence the achievable luminosity at the LHC experiments. Our calculated damage levels provide a very important input on how close to the beam these collimators can be operated without risk of damage. The results of this approach have been used already to push further the performance of the present machine. The risk of damage is even higher in the upgraded high-luminosity LHC with higher beam intensity, for which we quantify existing margins before equipment damage for the proposed baseline settings.

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Innovative MoC – graphite composite for thermal management and thermal shock applications

Bertarelli

Carra

Garlaschè

et al. 2015

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Status of the Commissioning of the LIGHT Prototype

Degiovanni¹,

Adam²,

Murciano³

et al. 2018

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Thermostructural characterization and structural elastic property optimization of novel high luminosity LHC collimation materials at CERN

Borg

Bertarelli

Carra

et al. 2018

Phys. Rev. Accel. Beams

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The CERN Large Hadron Collider is currently being upgraded to operate at a stored beam energy of 680 MJ through the High Luminosity upgrade. The LHC performance is dependent on the functionality of beam collimation systems, essential for safe beam cleaning and machine protection. A dedicated beam experiment at the CERN High Radiation to Materials facility is created under the HRMT-23 experimental campaign. This experiment investigates the behavior of three collimation jaws having novel composite absorbers made of copper diamond, molybdenum carbide graphite, and carbon fiber carbon, experiencing accidental scenarios involving the direct beam impact on the material. Material characterization is imperative for the design, execution, and analysis of such experiments. This paper presents new data and analysis of the thermostructural characteristics of some of the absorber materials commissioned within CERN facilities. In turn, characterized elastic properties are optimized through the development and implementation of a mixed numerical-experimental optimization technique.

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Paolo Gradassi

CERN Yellow Reports: Monographs, Vol. 10 (2020): High-Luminosity Large Hadron Collider (HL-LHC): Technical design report

Modeling of beam-induced damage of the LHC tertiary collimators

Innovative MoC – graphite composite for thermal management and thermal shock applications

Status of the Commissioning of the LIGHT Prototype

Thermostructural characterization and structural elastic property optimization of novel high luminosity LHC collimation materials at CERN

Contact Info

Product

Resources

About

Paolo Gradassi

CERN Yellow Reports: Monographs, Vol. 10 (2020): High-Luminosity Large Hadron Collider (HL-LHC): Technical design report

Modeling of beam-induced damage of the LHC tertiary collimators

Innovative MoC &#x2013; graphite composite for thermal management and thermal shock applications

Status of the Commissioning of the LIGHT Prototype

Thermostructural characterization and structural elastic property optimization of novel high luminosity LHC collimation materials at CERN

Contact Info

Product

Resources

About

Innovative MoC – graphite composite for thermal management and thermal shock applications