Scaling approach to nuclear structure in high-energy heavy-ion collisions

Jia, J.; Zhang, Chunjian

doi:10.48550/arxiv.2111.15559

Cited by 13 publications

(23 citation statements)

References 58 publications

(70 reference statements)

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“…We note, however, that almost all dependence is expected to cancel when taking the ratio between isobars that are as similar as 96 44 Ru and 96 40 Zr. All of our results agree qualitatively with AMPT studies [12,30] and as such our study is an important confirmation of those conclusions using a true hydrodynamic evolution. Nevertheless, we find that our v 3 {2} differs quantitatively.…”

supporting

confidence: 92%

“…This could have been anticipated from nuclear structure analyses [9,10], though we note significant differences between studies. It is the purpose of this Letter to utilise these different studies in the state-of-the-art heavy ion code Trajectum and show how recent results from DFT can fully explain the STAR findings (see also [11,12] for a similar study using the transport model AMPT for v 2 and v 3 ).…”

mentioning

confidence: 99%

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Inferring nuclear structure from heavy isobar collisions using Trajectum

Nijs¹,

Schee²

2021

Preprint

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Nuclei with equal number of baryons but varying proton number (isobars) have many commonalities, but differ in both electric charge and nuclear structure. Relativistic collisions of such isobars provide unique opportunities to study the variation of the magnetic field, provided the nuclear structure is well understood. In this Letter we simulate collisions using several state-of-the-art parametrizations of the 96 40 Zr and 96 44 Ru isobars and show that a comparison with the exciting STAR measurement [1] of ultrarelativistic collisions can uniquely identify the structure of both isobars. This not only provides an urgently needed understanding of the structure of the Zirconium and Ruthenium isobars, but also paves the way for more detailed studies of nuclear structure using relativistic heavy ion collisions.

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supporting

confidence: 92%

mentioning

confidence: 99%

Inferring nuclear structure from heavy isobar collisions using Trajectum

Nijs¹,

Schee²

2021

Preprint

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“…The Case 3 and Cases 7-10, skin-type and halo-type cases are taken from Xu's work [33] which considers the neutron-skin effect and/or a nuclear quadrupole deformity into the WS distribution with the TRENTO model. The Cases 4-6 are taken from Jia's recent researches [35,48], among which the Case 4 and Case 5 can well reproduce some experimental results. Meanwhile, the Case 6 is also from Ref.…”

Section: Introducing Geometry Configurations Of Isobar Nucleimentioning

confidence: 99%

“…It is worth noting that the Cases 4-6 and the effect of β 3 have been studied in detail in Refs. [35,48,51], and their recent study suggested that the ratios calculated at the same N ch provide a better baseline for the non-CME background [52]. For simplicity, we choose the halo-type neutron skin case for doing our following study related to the CME.…”

Section: Introducing Geometry Configurations Of Isobar Nucleimentioning

confidence: 99%

Search for the chiral magnetic effect in collisions between two isobars with nuclear structures

Zhao,

2022

Preprint

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Isobar collisions which were thought with a same background and different magnetic fields provide an opportunity to verify the chiral magnetic effect (CME) in relativistic heavy-ion collisions. However, the first result from the RHIC-STAR isobar experiment did not observed the CME signal, but discovered that the backgrounds are different between 96 44 Ru + 96 44 Ru and 96 40 Zr + 96 40 Zr collisions. We test eighteen cases of Woods-Saxon parameter settings resulted from different nuclear deformation or nuclear structure effects using a mutiphase transport model. We find out that seven cases can reasonably reproduce three reference ratios measured by the STAR experiment. With considering both the halo-type neutron skin structure and CME-like charge separation, we demonstrate that it is difficult for the CME observables (∆δ, ∆δ ratio, ∆γ and ∆γ/v 2 ratio) to distinguish the presence or absence of the CME, if the CME strength is weak in isobar collisions. It is because the final state interactions significantly weaken the initial CME signal, resulting in non-linear sensitivities of the CME observables to the CME strength. Therefore, more sensitive observables are required to search for the possible small CME signal in isobar collisions.

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“…isobar baseline and background estimations. Theoretical model calculations[78][79][80][81][82][83][84][85][86][87][88][89][90] are necessary to understand above physics. Unlike RIBLL, FRIB and NICA at low and medium energies, isobar collisions open up new opportunity to study nuclear structure at a very short time scale (∼ 10 −23 s) through heavy-ion collisions.• One fundamental property of light atomic nuclei in unusual nuclear structure…”

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confidence: 99%

An overview of new measurements of flow, chirality, and vorticity from STAR experiment

Zhang¹

2022

Preprint

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In relativistic heavy-ion collisions, the properties of quark-gluon plasma (QGP) and complex dynamics of multi-scale processes in Quantum Chromodynamics (QCD) are studied by analyzing the final state produced particles in a variety of different ways. In these proceedings, we present an overview of new detailed measurements of flow, chirality, and vorticity by the STAR experiment at RHIC. Furthermore, STAR's future opportunities for the precision measurements on small systems, fixed-target (FXT) mode, and Beam Energy Scan (BES-II) program are discussed.

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Scaling approach to nuclear structure in high-energy heavy-ion collisions

Cited by 13 publications

References 58 publications

Inferring nuclear structure from heavy isobar collisions using Trajectum

Inferring nuclear structure from heavy isobar collisions using Trajectum

Search for the chiral magnetic effect in collisions between two isobars with nuclear structures

An overview of new measurements of flow, chirality, and vorticity from STAR experiment

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