Improved Pion-Kaon Identification in Heavy-Ion Collisions with a Two-Dimensional Transformation

Abstract

Accurate identification of charged pions and kaons is essential for precision measurements in relativistic heavy-ion collisions, but becomes increasingly challenging at intermediate and high transverse momentum due to the overlap between time-of-flight mass-square (m2) and ionization energy loss (nσ) distributions. In this work, we present a two-dimensional shift and rotation method that exploits the correlated information between m2 and nσ to enhance particle identification performance. The method is validated using Au+Au collision events generated with the AMPT model, where detector response effects are incorporated through a data-driven smearing procedure tuned to reproduce the particle identification performance of the STAR experiment. The reconstructed pion and kaon transverse momentum distributions show excellent agreement with the AMPT input, maintaining a purity exceeding 98\% at high pT and extend the reliable identification range up to pT ≈ 3 GeV/c. The extracted elliptic flow v2 remains consistent with the input over the extended pT range, demonstrating that the proposed method provides a robust framework for high precision identified hadron measurements.