Generic framework for anisotropic flow analyses with multiparticle azimuthal correlations

Ante Bilandzic; Christian Holm Christensen; Kristjan Herlache Gulbrandsen; Alexander Colliander Hansen; You Zhou

Generic framework for anisotropic flow analyses with multiparticle azimuthal correlations

Ante Bilandzic, Christian Holm Christensen, Kristjan Herlache Gulbrandsen, Alexander Colliander Hansen, You Zhou

Experimental Particle Physics

128 Citations (Scopus)

Abstract

We present a new generic framework which enables exact and efficient evaluation of all multiparticle azimuthal correlations. The framework can be readily used along with a correction framework for systematic biases in anisotropic flow analyses owing to various detector inefficiencies. A new recursive algorithm has been developed for higher-order correlators for the cases where their direct implementation is not feasible. We propose and discuss new azimuthal observables for anisotropic flow analyses which can be measured for the first time with our new framework. The effect of finite detector granularity on multiparticle correlations is quantified and discussed in detail. We point out the existence of a systematic bias in traditional differential flow analyses which stems solely from the applied selection criteria on particles used in the analyses and is also present in the ideal case when only flow correlations are present. Finally, we extend the applicability of our generic framework to the case of differential multiparticle correlations.

Original language	English
Article number	064904
Journal	Physical Review C (Nuclear Physics)
Volume	89
Issue number	6
ISSN	0556-2813
Publication status	Published - 9 Jun 2014

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http://dx.doi.org/10.1103/PhysRevC.89.064904

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title = "Generic framework for anisotropic flow analyses with multiparticle azimuthal correlations",

abstract = "We present a new generic framework which enables exact and efficient evaluation of all multiparticle azimuthal correlations. The framework can be readily used along with a correction framework for systematic biases in anisotropic flow analyses owing to various detector inefficiencies. A new recursive algorithm has been developed for higher-order correlators for the cases where their direct implementation is not feasible. We propose and discuss new azimuthal observables for anisotropic flow analyses which can be measured for the first time with our new framework. The effect of finite detector granularity on multiparticle correlations is quantified and discussed in detail. We point out the existence of a systematic bias in traditional differential flow analyses which stems solely from the applied selection criteria on particles used in the analyses and is also present in the ideal case when only flow correlations are present. Finally, we extend the applicability of our generic framework to the case of differential multiparticle correlations.",

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T1 - Generic framework for anisotropic flow analyses with multiparticle azimuthal correlations

AU - Bilandzic, Ante

AU - Christensen, Christian Holm

AU - Gulbrandsen, Kristjan Herlache

AU - Hansen, Alexander Colliander

AU - Zhou, You

PY - 2014/6/9

Y1 - 2014/6/9

N2 - We present a new generic framework which enables exact and efficient evaluation of all multiparticle azimuthal correlations. The framework can be readily used along with a correction framework for systematic biases in anisotropic flow analyses owing to various detector inefficiencies. A new recursive algorithm has been developed for higher-order correlators for the cases where their direct implementation is not feasible. We propose and discuss new azimuthal observables for anisotropic flow analyses which can be measured for the first time with our new framework. The effect of finite detector granularity on multiparticle correlations is quantified and discussed in detail. We point out the existence of a systematic bias in traditional differential flow analyses which stems solely from the applied selection criteria on particles used in the analyses and is also present in the ideal case when only flow correlations are present. Finally, we extend the applicability of our generic framework to the case of differential multiparticle correlations.

AB - We present a new generic framework which enables exact and efficient evaluation of all multiparticle azimuthal correlations. The framework can be readily used along with a correction framework for systematic biases in anisotropic flow analyses owing to various detector inefficiencies. A new recursive algorithm has been developed for higher-order correlators for the cases where their direct implementation is not feasible. We propose and discuss new azimuthal observables for anisotropic flow analyses which can be measured for the first time with our new framework. The effect of finite detector granularity on multiparticle correlations is quantified and discussed in detail. We point out the existence of a systematic bias in traditional differential flow analyses which stems solely from the applied selection criteria on particles used in the analyses and is also present in the ideal case when only flow correlations are present. Finally, we extend the applicability of our generic framework to the case of differential multiparticle correlations.

M3 - Journal article

SN - 2469-9985

VL - 89

JO - Physical Review C

JF - Physical Review C

IS - 6

M1 - 064904

ER -

Generic framework for anisotropic flow analyses with multiparticle azimuthal correlations

Abstract

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