Combined constraints on dark photons from high-energy collisions, cosmology, and astrophysics

Abstract

We investigate a dark sector coupled to the Standard Model (SM) through a kinetically mixed dark photon U associated with a new U(1)' gauge symmetry. Kinetic mixing induces an effective coupling to the electromagnetic current, while U interacts with stable dark matter (DM) via a dark gauge coupling g. Our analysis is based on the parton-hadron-string dynamics (PHSD) transport approach, extended to include dark photon production and decay into dileptons (U\! e+e-). In PHSD, dark photons are produced in high-energy collisions through Dalitz decays of light mesons (π0,η,η',ω), Delta-resonances (\! N U), direct vector meson decays (,ω,φ\! U), kaon decays, and q q\! U annihilation. Building on previous PHSD benchmarks against dilepton data, we extract upper limits on 2(mU,m,α) in both the visible regime (mU<2m), where U\! e+e- dominates, and the invisible regime (mU>2m), where U\! is kinematically open. Cosmological and astrophysical constraints are incorporated in two complementary ways. First, we compute the velocity-dependent self-interaction cross section σ/m for Yukawa-mediated SIDM and confront it with bounds from dwarf galaxies, galaxy groups, and clusters. Second, we determine thermal relic target curves by computing the relic abundance and requiring DMh2 0.12, consistent with Planck measurements of the cosmic microwave background. Combining PHSD limits on 2 with relic density and self-interaction requirements, we exclude regions of the (m,mU) plane for each DM realization (Dirac, Majorana, or complex scalar) and identify benchmark scenarios in which heavy-ion, cosmological, and astrophysical constraints are simultaneously satisfied.