Exceptional Points revealed by the integrated imaginary scattering eigenphase

We propose and analytically demonstrate that the eigenphases of the scattering matrix provide direct, phase-sensitive signatures of exceptional points in open PT-symmetric systems. Using a one-dimensional PT-symmetric quantum dimer with balanced gain and loss, coupled to continuum leads, we track the evolution of the scattering eigenphases across the PT-exact to PT-broken transition. The imaginary parts of the eigenphases develop localized structures of opposite sign as the exceptional point is approached, reflecting the emergence of gain/loss asymmetry in the scattering eigenmodes. We introduce the integrated imaginary scattering eigenphase G(gamma), which condenses this information into a single experimentally accessible scalar. G(gamma) is negligibly small in the PT-exact phase and undergoes a sharp transition -- a pronounced inflection followed by saturation into a plateau -- near the exceptional point. The inflection point of G(gamma) precedes gamma_{EP} and coincides with the maximum amplitude of the transmission resonances, revealing that peak gain/loss asymmetry and eigenstate coalescence are governed by independent conditions in open systems -- a direct fingerprint of their finite coupling to the continuum. Because the analysis is formulated entirely at the level of the S-matrix -- without reference to any specific physical realization -- the results are universally applicable across wave systems, including photonic, acoustic, and microwave platforms where phase-resolved measurements are available.