In-flight confinement of an electron surfing on a sound wave

Surface acoustic waves (SAW) have large potential to realize quantum-optics-like experiments with single flying electrons employing their spin or charge degree of freedom. For such quantum applications, highly efficient trapping of the electron in a specific moving quantum dot (QD) of a SAW train plays a key role. So far, detailed knowledge on the specific confinement threshold is however missing. Here we fill this gap by demonstrating time-of-flight measurements for a single electron that is transported via a SAW train between distant stationary QDs. We find that for an acousto-electric amplitude larger than (23 $\pm$ 3) meV, the dynamic confinement potential is sufficiently large to confine the flying electron in a deliberately chosen moving QD of the SAW train. Investigating the effect of a barrier along the transport channel, we also benchmark the robustness of SAW-driven electron transport against stationary potential variations. Our results pave the way for highly controlled transport of electron qubits in a novel SAW-driven platform for quantum experiments.