We theoretically demonstrate that planar rectangular dielectric waveguides can support in-plane transmission of optical vortex modes, carrying orbital angular momentum. As compared with the existing works, in our manuscript this problem is investigated for the general case of the azimuthal order of the mode. We believe that our results will broaden the current understanding of the problem and can pave the way towards novel applications of optical vortices based on photonic integrated circuits.

We study analytically and numerically the possibility of vortex modes propagation over planar dielectric rectangular waveguides, and consider the problem of waveguide geometry optimization for the support of vortex modes. The results show, that theoretically rectangular waveguides can provide transmission of quasi-TE and quasi-TM modes with high purity states of orbital angular momentum (OAM) in the dominant field component. However, only for the quasi-generate mode of azimuthal order ±1 the constituent eigenmodes can propagate in a phase-matched regime, and the vortex modes of higher azimuthal orders can propagate only with a certain beat length. Moreover, as the target azimuthal order increases, the normalized power of the corresponding OAM state in the modal superposition decreases. The analytical predictions have been verified by numerical electromagnetic simulations of silicon nitride waveguides providing field distributions and OAM spectra of the corresponding modal superpositions.