Atomic and Molecular Waveform Processing with Attosecond Resolution
Abstract
Advancing the temporal resolution in computations, signal generation and modulation, and measurements is of paramount importance for pushing the boundaries of science and technology. Optical resonators have recently demonstrated the ability to perform computational operations at frequencies beyond the gigahertz range, surpassing the speed of conventional electronic devices. However, increasing the resonator length extends the operation time but decreases the temporal resolution, with current state-of-the-art systems achieving only picosecond resolution. Here we show that atoms and molecules belong to the class of widely-used passive resonators that operate without gain, such as subwavelength particles, electric circuits, and slabs, but with long operation times and, importantly, attosecond resolution. Our analysis reveals that when resonantly exciting atoms and molecules, the resulting scattered field is the integral of the incoming field envelope, with improvement factors in temporal resolution of a million and trillion compared with optical resonators and electronic devices, respectively. We demonstrate our results theoretically for atoms and compare it with the standard slab resonator. Remarkably, our approach applies to all transition types including electronic, vibrational, rotational, and spin, with the same temporal resolution preserved across all frequencies. Our research paves the way for a new generation of devices operating on attosecond timescales and opens new avenues in fields such as computation, ultrafast phenomena, high-rate data transmission, encryption, and quantum technology.