Angular correlations measured in p-p and heavy ion collisions at the Relativistic Heavy Ion Collider (RHIC) include a same-side (SS) 2D peak. In peripheral A-A and p-p collisions the SS peak properties are consistent with predicted minimum-bias jet correlations. However, in more-central Au-Au collisions the SS peak becomes elongated on pseudorapidity eta. Arguments have been proposed to explain the SS peak eta elongation in terms of possibly fluctuating initial-state geometry multipoles coupled with radial flow to produce final-state momentum-space multipoles. Such arguments are based on Fourier decomposition of 2D angular correlations projected onto 1D azimuth. In this analysis we show that measured correlation structure on eta (large curvatures) establishes a clear distinction between the SS 2D (jet) peak and 1D multipoles. Measured 2D peak systematics can predict inferred 1D Fourier amplitudes interpreted as 'higher harmonic flows'. However, 1D Fourier amplitudes alone cannot describe 2D angular correlations. The SS 2D peak remains a unique structure that can be interpreted in terms of parton scattering and fragmentation in all cases.

• 出版日期2013-5