A Platform for a Wheeler's Delayed-Choice Experiment in Optical Fiber

Abstract: Quantum mechanics has played a big role in the development of our understanding of the smallest things in the universe. It has provided descriptions for phenomena like single electrons or single photons, which are single particles of light. One of the most mysterious properties of quantum systems is the ability to behave as a particle or a wave. In 1978, J. A. Wheeler devised an experiment to investigate if a quantum system knows in advance if it should propagate as a wave or as a particle through an experiment, by changing the experiment after the quantum system has entered the experimental set-up.  Here an optical all-in fiber platform for a Wheeler's delayed choice experiment is modeled, constructed and tested using commercially available fiber optic components. This is in contrast to previous delayed choice experiments, which have used free-space components in some parts of their experimental set-up. The optical set-up was modeled and simulated using a quantum formalism, with future work in mind if the platform is used to perform a quantum delayed-choice experiment. The platform used a Sagnac interferometer as the second beamsplitter in a Mach-Zehnder interferometer, to perform the choice of measuring either particle or wave properties. Using a fiber platform, the length of the platform can easily be extended with more fiber to accommodate a large separation between the beamsplitter in the beginning of the set-up, and the Sagnac interferometer at the end of the set-up. The result was a stable platform to measure particle behavior of light with good performance, and the ability to switch between these measurements on the fly. The system was tested with classical light, but the light source can be changed from a laser, to for example an attenuated laser, to enter the quantum domain for performing a quantum delayed-choice experiment using the platform.