The Nuclotron-based Ion Collider Facility Project. The Physics Programme for the Multi-Purpose Detector

Geraksiev, N.

doi:10.1088/1742-6596/1023/1/012030

Cited by 5 publications

(4 citation statements)

References 11 publications

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“…In future fixed target experiments, with much more statistics of low energy data, we can perform precise measurements of those higher order cumulants of conserved charges at the high baryon density region. Heavy Flavor Production: FAIR-CBM and NICA-MPD experiments with advanced fast detector technology under high luminosity beam condition will provide unique chance to measure open and hidden charm hadrons with large statistics close to the production energy threshold [162,218]. It is expected that this measurements will improve the precision of the total charm cross section at low energies and will provide constraints on pQCD calculations, as well as the unknown interactions between charmed particles and cold hadronic medium.…”

Section: Future Upgrades and Physics Program At High Baryon Density R...mentioning

confidence: 99%

A Study of the Properties of the QCD Phase Diagram in High-Energy Nuclear Collisions

Luo

Shi

et al. 2020

Particles

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With the aim of understanding the phase structure of nuclear matter created in high-energy nuclear collisions at finite baryon density, a beam energy scan program has been carried out at Relativistic Heavy Ion Collider (RHIC). In this mini-review, most recent experimental results on collectivity, criticality and heavy flavor productions will be discussed. The goal here is to establish the connection between current available data and future heavy-ion collision experiments in a high baryon density region.Particles 2020, xx, 5 0 -5% 60 -80% 0 -5% Au+Au at RHIC Pb+Pb at LHC A. Andronic, et al., NPA834, 237(10) J. Cleymans, et al., PRC73, 34905(06) Lattice fits

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Section: Future Upgrades and Physics Program At High Baryon Density R...mentioning

confidence: 99%

A Study of the Properties of the QCD Phase Diagram in High-Energy Nuclear Collisions

Luo

Shi

et al. 2020

Particles

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“…The cylindrical part of TOF also has full azimuthal and |η| < 1.2 coverage and will allow PID in the p T range 0.1 -2 GeV/c for charged hadrons. Combining the measurements from TPC and TOF will provide an efficient π/K PID separation up to 1.5 GeV/c and π/p separation up to 3 GeV/c [160]. Initial run of NICA will be done with Bi+Bi collisions at √ s N N = 9.2 AGeV [161].…”

Section: Nicamentioning

confidence: 99%

Search for the QCD Critical Point in High Energy Nuclear Collisions

Pandav,

Mallick,

Mohanty

2022

Preprint

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QCD critical point is a landmark region in the QCD phase diagram outlined by temperature as a function of baryon chemical potential. To the right of this second-order phase transition point, one expects first order quark-hadron phase transition boundary, towards the left a crossover region, top of it lies the quark gluon plasma phase and below it the hadronic phase. Hence locating the QCD critical point through relativistic heavy-ion collision experiments is an active area of research. Cumulants of conserved quantities in strong interaction, such as net-baryon, net-charge, and net-strangeness, are suggested to be sensitive to the physics of QCD critical point and are therefore useful observables in the study of the phase transition between quark-gluon plasma and hadronic matter. We review the experimental status of the search for the QCD critical point via the measurements of cumulants of net-particle distributions in heavy-ion collisions. We discuss various experimental challenges and associated corrections in such fluctuation measurements. We also comment on the physics implications of the measurements by comparing them with theoretical calculations. This is followed by a discussion on future experiments and measurements related to high baryonic density QCD matter.

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“…In the second type of experiments, two beams accelerated in opposite directions are collided at interaction points. In this case, one can distinguish, among others, STAR (Solenoidal Tracker at RHIC) [17], ALICE (A Large Ion Collider Experiment) [18], CMS (Compact Muon Solenoid) [19], ATLAS (A Toroidal LHC ApparatuS) [20], MPD (Multi-Purpose Detector) [21] experiments. In both cases, in the areas of ion collisions, groups of scientists set up an experimental set-up made of multiple detectors.…”

Section: Multi-detector Experimentsmentioning

confidence: 99%

Practical Digital Twins Application to High Energy Systems: Thermal Protection for Multi-Detector

et al. 2022

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The digital twins concept brings a new perspective into the system design and maintenance practice. As any industrial process can be accurately simulated, its digital replica can be utilized to design a control system structure, evaluate its efficacy and investigate the properties of the real system and possible issues. Based on such an analysis, ideas for improvement may be formulated. This article reports the formulation of a digital twin system developed for a Thermal System (TS) maintaining proper thermal conditions for the operation of the Silicon Tracking Detectors (STDs) utilized for high-energy physics experiments. A thermal system digital twin is built for a full-scale target installation, which is right now during the construction phase. The emphasis is put on a proper control system design using the thermal system digital twins.

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The Nuclotron-based Ion Collider Facility Project. The Physics Programme for the Multi-Purpose Detector

Cited by 5 publications

References 11 publications

A Study of the Properties of the QCD Phase Diagram in High-Energy Nuclear Collisions

A Study of the Properties of the QCD Phase Diagram in High-Energy Nuclear Collisions

Search for the QCD Critical Point in High Energy Nuclear Collisions

Practical Digital Twins Application to High Energy Systems: Thermal Protection for Multi-Detector

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