Important part of JINR’s obligations in modernisation of CMS Facility at CERN fulfiled
News, 16 April 2024
The JINR scientists, within the framework of the second phase of modernization of the CMS facility, currently participate in the project to develop a calorimeter with high granularity HGCaL that will significantly increase spatial and temporal resolution and will be able to operate efficiently in the high luminosity conditions of the Large Hadron Collider at CERN. A facility for testing the HGCaL Calorimeter was designed and developed in the Veksler and Baldin Laboratory of High Energy Physics. The VBLHEP staff delivered the facility for testing at CERN, where it was assembled and configured. Head of the CMS Scientific and Experimental Physics Department Vladimir Karzhavin spoke about progress and results of the work.
The HGCaL calorimeter consists of 47 sequentially arranged absorber layers (along the beam), with cassettes positioned in the gaps between them. Geometrically, they are 30- or 60-degree segments with active devices of the detector mounted on copper cooling panels. Scintillation cells with light registration using SiPM and silicon sensor units positioned in the area of strong radiation load are used as detecting components. In total, the calorimeter uses 660 cassettes of various configurations (with a total weight of more than 215 tons for one end part). The calorimeter operates in a thermally insulated volume at a temperature of -30°C.
Sergei Afanasiev and Alexander Malakhov are discussing the results of testing thermally insulated chambers
Specialists from JINR and the Belarusian State University (Minsk) have developed a technology for manufacturing cooling plates for HGCaL calorimeter cassettes. Physicists and engineers of VBLHEP JINR are extensively involved in the development of a stand to test the operability and properties of the cassettes after assembly. For possessing such a stand in Russia, two thermally insulated chambers were manufactured and delivered to CERN. After assembly, the cassettes are tested under conditions close to real ones, at a temperature of -30°C.
Cassettes in the amount of 10 pieces are installed in a rack positioned inside a thermally insulated chamber measuring 3.0 x 3.0 x 2.5 m. Two 2.4 x 3.0 m scintillation trigger planes are positioned at the top and bottom of the thermally insulated chamber to test the operability and to measure the properties of the detecting components and electronics positioned on the HGCaL cassettes using cosmic rays.
Valentin Ustinov is adjusting the trigger planes of the stand for measuring the properties of the hadronic calorimeter cassettes
When cosmic particles pass through a complex of tested cassettes, the activation of the corresponding sensors is registered using the readout electronics and if they coincide with the trigger signal, confirms the functionality of the sensor. A Monte Carlo model of a test stand in cosmic rays has been developed, with the help of which the dimensions of the trigger planes and the configuration of the scintillator plates are optimized.
Developing a stand for testing cassettes was carried out under the supervision of Sergei Afanasiev and Alexander Malakhov. VBLHEP physicists and engineers V. V. Ustinov, E. V. Sukhov, N. V. Gorbunov, A. M. Kurenkov, Yu. Vershov, P. D. Bunin and B. V. Dubinchik took an active part in this work. Great assistance in the implementation of this stage of the CMS modernization project was provided by JINR Scientific Leader, Academician of the Russian Academy of Sciences Victor Matveev.