Low-threshold efficient N2+ lasing driven by sub-cycle soliton dynamics in a hollow waveguide

Abstract

The phenomenon of N2+ lasing, observed in femtosecond-laser filamentation, attract considerable interests in recent several years, with great application potentials in fields of remote sensing and ultrafast spectroscopy. Efficient N2+ lasing at relatively-low pump energies and with high beam quality, while being highly-demanded for applications, remains, however, quite challenging in practical experiments. Here, we demonstrate a new route of generating low-threshold N2+ lasing with unprecedently-high efficiency, which is enabled by soliton dynamics in a gas-filled hollow-tapered-capillary system. High-order-soliton compression of a 12-fs, 10-μJ-level pump pulse forms a sub-cycle asymmetric transient that tunnel-ionizes N2 to N2+ and, through direct, single-photon resonant excitation, creates population inversion between the ground state X2Σg+ and the excited state B2Σu+-a dynamic process distinct from the widely adopted three-state coupling picture-and remarkably at unexpectedly low pump energy. In the experiments, we obtained 100-nJ-level N2+ lasing pulses at 391 nm with conversion efficiencies up to 3.3×10-3, at pump energies of less than 50 μJ. These results represent improvement of more than one orders of magnitude in both generation efficiency and lasing threshold, compared with prevailing filamentation-based schemes. Our study bridges two generally-disparate fields (sub-cycle soliton dynamics and N2+ lasing), and paves the way for narrow-band, high-beam-quality lasing pulses that may find wide applications in advanced spectroscopy and nonlinear pump-probe experiments.