Exceptional point in a PT symmetric non-Hermitian terahertz plasmonic metasurface (2506.17906v1)

Abstract: In this paper, we experimentally demonstrate a non-Hermitian open PT-symmetric terahertz metasurface comprising complementary plasmonic structures capable of exhibiting an exceptional point (EP). The metasurface consists of two resonators of different sizes, representing effective gain and loss elements, placed orthogonally in close proximity to realize a non-Hermitian configuration leading to a PT symmetry state. A diagonal displacement of one resonator within this strongly coupled near-field configuration leads to the emergence of an exceptional point, where the system undergoes a sudden phase transition from a PT symmetric to a PT-asymmetric state. Terahertz time-domain spectroscopy (THz-TDS) is performed on the fabricated samples to experimentally validate the phase transition observed in numerical simulations. We employ coupled mode theory (CMT) to analyse and distinguish between the PT-symmetric, exceptional point, and PT-asymmetric states. This theoretical framework enables the calculation of eigenvalues, phase spectra, and eigenmodes associated with the metamaterial design, thereby corroborating the simulation results. Furthermore, we construct Poincare sphere to visualize the orientation of the polarization states of the eigenmodes, which further indicates the presence of the exceptional point. This comprehensive study of exceptional point in a plasmonic system holds potential for the development of practical, highly sensitive terahertz devices, addressing limitations of conventional PT-symmetric systems that rely on traditional gain and loss media.