摘要
Valuable information on dynamics of expanding fluids can be inferred from the response of such systems to perturbations in their initial geometry.We apply this technique in high-energy^(96)Ru+^(96)Ru and^(96)Zr+^(96)Zr collisions to scrutinize the expansion dynamics of the quark-gluon plasma,where the initial geometry perturbations are sourced by the differences in deformations and radial profiles between^(96)Ru and^(96)Zr,and the collective response is captured by the change in anisotropic flow Vn between the two collision systems.Using a transport model,we analyze how the nonlinear coupling between lower-order flow harmonics V_(2)and V_(3)to the higher-order flow harmonics V_(4)and V_(5),expected to scale as V_(4)NL= χ_(4)V_(2)2and V_(5)NL= χ_(5)V_(2)V_(3),gets modified as one moves from^(96)Ru+^(96)Ru to^(96)Zr+^(96)Zr systems.We find that these scaling relations are valid to high precision:variations of order 20% in V_(4)NLand V_(5)NLdue to differences in quadrupole deformation,octupole deformation,and nuclear skin modify χ_(4)and χ_(5)by about 1–2%.Percent-level deviations are however larger than the expected experimental uncertainties and could be measured.Therefore,collisions of isobars with different nuclear structures are a unique tool to isolate subtle nonlinear effects in the expansion of the quark-gluon plasma that would be otherwise impossible to access in a single collision system.
作者
贾江涌
Giuliano Giacalone
张春健
Jiangyong Jia;Giuliano Giacalone;Chunjian Zhang(Department of Chemistry,Stony Brook University,Stony Brook,NY 11794,USA;Physics Department,Brookhaven National Laboratory,Upton,NY 11976,USA;Institut fur Theoretische Physik,Universitat Heidelberg,Philosophenweg 16,69120 Heidelberg,Germany)
基金
supported by DOE DE-FG02-87ER40331
funded by the Deutsche Forschungsgemeinschaft (DFG,German Research Foundation) under Germanys Excellence Strategy EXC2181/1-390900948 (the Heidelberg STRUCTURES Excellence Cluster),within the Collaborative Research Center SFB1225 (ISOQUANT,Project-ID 273811115)。
