Probing triaxial deformation of atomic nuclei in high-energy heavy ion collisions

Abstract

Most atomic nuclei are deformed with a quadrupole shape described by its overall strength β2 and triaxiality γ. The deformation can be accessed in high-energy heavy-ion collisions by measuring the collective flow response of the produced quark-gluon plasma to the eccentricity 2 and the density gradient d in the initial state. Using analytical estimate and a Glauber model, I show that the variances, 22 or (δ d/d)2, and skewnesses, 22δ d/d or (δ d/d)3, have a simple analytical form of a'+b'β22 and a'+(b'+c'(3γ))β23, respectively. From these, I constructed several normalized skewnesses to isolate the γ dependence from that of β2, and show that the correlations between any normalized skewness and any variance can constrain simultaneously the β2 and γ. Assuming a linear relation with elliptic flow v2 and mean-transverse momentum [pT] of final state particles, similar conclusions are also expected for the variances and skewnesses of v2 and [pT]. Our findings motivate a dedicated system scan of high-energy heavy ion collisions to measure triaxiality of atomic nuclei. This is better done by collisions of prolate, (3γ)=1, and oblate nuclei, (3γ)=-1, with well known β2 values to calibrate the coefficients b' and c', followed by collisions of species of interest especially those with known β2 but unknown γ. The results demonstrate the unique opportunities offered by high-energy collisions as a tool to perform interdisciplinary nuclear physics studies.