Abstract: This paper presents the first measurements of the azimuthal anisotropy coefficients vn, which quantify the nth-order Fourier modulation of charged-particle azimuthal distributions, for n = 2-4 in root s(NN) = 5.36 TeV O-16+ O-16 and Ne-20+ Ne-20 collisions recorded with the ATLAS detector at the CERN Large Hadron Collider in 2025. The v(n) coefficients are measured as a function of transverse momentum (p(T)), collision centrality, and event multiplicity. They are extracted using two complementary methods: two-particle correlations with a template-fit subtraction of short-range nonflow contributions, and four-particle subevent cumulants, which intrinsically suppress nonflow effects and provide sensitivity to flow fluctuations. The results show a clear hierarchy v(2) > v(3) > v(4) and a nonmonotonic dependence on p(T), reaching a maximum around 2 GeV, consistent with trends observed in heavy-ion collisions. Detailed comparisons between the two collision systems reveal an enhanced v(2) in central Ne-20+ Ne-20 collisions, consistent with theory expectations based on the predicted prolate deformation of neon nuclei, in contrast to the slightly tetrahedral structure predicted for oxygen. The four-particle cumulant results highlight strong event-by-event fluctuations and provide the greatest sensitivity to nuclear shape effects. These measurements can place new constraints on the initial geometry and the hydrodynamic response in light-ion collisions, offering valuable input for models of nuclear structure.

Abstract: In this study, we explore temperature-dependent CPT violation during big bang nucleosynthesis (BBN) through electron-positron mass asymmetries parametrized by b0(T) 1/4 alpha T2. The T2 scaling naturally evades stringent laboratory bounds at zero temperature while allowing for significant CPT violation at MeV scales in the early Universe [S. Navas et al. (Particle Data Group), Phys. Rev. D 110, 030001 (2024)]. Using a modified version of the BBN code PRyMordial with dynamically-solved chemical potentials and appropriate finite-mass corrections, we constrain electron-positron mass differences from observed abundances of helium-4, deuterium, and Neff. We find that alpha must be greater than or approximately equal to 10-6 GeV-1 for keV-scale mass differences at BBN. All three observables show no simultaneous 1 sigma overlap, though pairwise combinations allow for constrained regions of parameter space. We present two toy models demonstrating how b0(T) proportional to T2 arises from field-theoretic mechanisms, including temperature-driven phase transitions. These results provide the most stringent constraints on early-Universe CPT violation in this regime, probing parameter space inaccessible to laboratory experiments.

Abstract: Axionlike particles (ALPs) provide a well-motivated framework for physics beyond the Standard Model, coupling to gauge bosons through dimension-five operators protected by an approximate shift symmetry. At the LHC, such interactions lead to distinctive signatures in multiboson production, where the ALP appears as an off-shell mediator rather than a narrow resonance. In this work, we present the first global and vector-boson-fusion (VBF) final states. On the theory side, motivated from a UV perspective, we assume that the ALP couples only to the gauge sector of the SM and classify the ALP-multiboson vertices that directly modify collider observables. Using Run-2 LHC measurements, we extract bounds on the Wilson coefficients (cG, c W, cB) that parametrize gluonic and electroweak ALP interactions. Our results show that the dijet channel dominates the sensitivity to ALP couplings and determines the limits on cG, while diboson and VBF processes provide complementary constraints on the electroweak couplings. We further assess the validity of the effective field theory expansion at the multi-TeV scales probed by the data. This global study provides the most comprehensive picture to date of ALP-gauge interactions from multiboson production at the LHC and highlights the opportunities for significant improvements with future high-luminosity measurements.