English

How transverse momentum conservation breaks azimuthal correlation factorization

Nuclear Theory 2026-01-28 v1 High Energy Physics - Phenomenology Nuclear Experiment

Abstract

The breakdown of azimuthal two-particle correlation factorization, quantified by the ratios r2r_2 and r3r_3, serves as a sensitive probe of transverse-momentum-dependent flow fluctuations. While hydrodynamic models predict r31r_3 \leq 1, experimental data from CMS in p-Pb collisions exhibit r3>1r_3 > 1, presenting a clear puzzle. We show that transverse momentum conservation (TMC) is the key mechanism dictating this factorization breakdown in small systems. We systematically calculate the effect of TMC as a function of the momentum difference between particles across various multiplicity and momentum ranges. Our results are in quantitative agreement with CMS p-Pb data for both r2r_2 and r3r_3. A central finding is a sign rule: under TMC, the deviation rn1r_n - 1 follows (1)n+1\left ( - 1 \right )^{n+1} , being negative for even and positive for odd harmonic orders nn. This work establishes an analytical framework to quantify transverse-momentum-dependent flow fluctuations and provides new insights into the origin of collectivity in small colliding systems.

Cite

@article{arxiv.2601.19475,
  title  = {How transverse momentum conservation breaks azimuthal correlation factorization},
  author = {Jia-Lin Pei and Guo-Liang Ma and Adam Bzdak},
  journal= {arXiv preprint arXiv:2601.19475},
  year   = {2026}
}

Comments

17 pages, 9 figures

R2 v1 2026-07-01T09:22:05.703Z