Generation of subcycle isolated attosecond pulses by pumping ionizing gating

Gating techniques have been widely used for the generation of isolated attosecond pulses(IAPs) by limiting the high harmonics generation(HHG) within one optical cycle of the driving laser. However, as only one optical cycle is taken advantaged, the IAP the energy can hardly be enhanced by using a long driving pulse. In this letter, we present a regime named pumping ionizing gating(PIG) to generate IAPs. Instead of traditional ionizing gating, a long pump dynamically reflected by fast-extending plasma grating(FEPG) is employed to continuously inject the energy to the driving(ionizing) pulse. The overlapping region of the pump reflection and frequency upconversion forms a narrow PIG, which opens a door to transfer the long-pump energy to IAPs. This regime is demonstrated by the particle-in-cell(PIC) simulation, at extremely wide plasma densities(0.02nc-0.5nc) and FEPG modulation depths(10%-60%). The three dimensional(3D) simulation shows a 330 as laser pulse is obtained by a 1.6-ps 1-$\mu$m pump, with the peak intensity 33 times as the pump, and a conversion efficiency around 0.1%.