Goal of this paper has been to propose: (i) photon angular momentum based deterministic universal quantum qudit gates, (ii) different quantum modules of importance for various applications including (fault-tolerant) quantum computing, teleportation, QKD, and quantum error correction; (iii) integrated optics implementation of proposed modules; and (iv) entanglement assisted protocols employing the proposed generalized-Bell-state generation module and study their security when OAM modes are imperfectly generated.

To address key challenges for both quantum communication and quantum computing applications in a simultaneous manner, we propose to employ the photon angular momentum approach by invoking the well-known fact that photons carry both the spin angular momentum (SAM) and the orbital angular momentum (OAM). SAM is associated with polarization, while OAM is associated with azimuthal phase dependence of the complex electric field. Given that OAM eigenstates are mutually orthogonal, in principle, an arbitrary number of bits per single photon can be transmitted. The ability to generate/analyze states with different photon angular momentum, by using either holographic or interferometric methods, allows the realization of quantum states in multidimensional Hilbert space. Because OAM states provide an infinite basis state, while SAM states are 2-D only, the OAM can also be used to increase the security for quantum key distribution (QKD) applications and improve computational power for quantum comp...