Observation of space-time nonseparable helical pulses

Chirality is a fascinating natural phenomenon with widespread applications in scientific research. Toroidal responses, distinct from chiral responses, represent an emerging and intriguing field that investigates toroidal electromagnetic phenomena. This field has garnered significant attention following the first experimental observations of oscillating toroidal dipoles and electromagnetic toroidal pulses. Breaking the symmetry of toroidal responses and observing chiral toroidal responses are crucial for advancing our understanding of toroidal phenomena and expanding the theoretical and practical applications of toroidal electrodynamics. Here, we present two complementary methods for breaking the symmetry of toroidal pulses and generating chiral space-time nonseparable helical pulses (SNHPs)-quasi-linearly polarized and chiral toroidal-across the optical and microwave spectral ranges. This was achieved through polarization decomposition of toroidal light pulses and direct emission from an ultrawideband spiral antenna, respectively. These advancements pave the way for experimental investigations into information transfer and light-matter interactions involving chiral SNHPs, including toroid-vortex coupling, classical-quantal entanglement, and optical machining, all of which are of growing interest in both fundamental science and practical applications.