Bidirectional Quantum Teleportation in Presence of Dephasing

Perfect quantum teleportation relies on a maximally entangled channel shared between two users. However, inherent decoherence effects make this idea difficult to achieve in practice. Specifically, dephasing causes phase randomization, leading to information loss and reduced fidelity in quantum teleportation. This study examines the impact of dephasing on bidirectional quantum teleportation (BQT) by analyzing the average fidelity of BQT under different environmental conditions. Results show that the average fidelity remains above the classical limit of 2/3 for various bath spectral densities like (sub-ohmic (s<1 ), ohmic ( s=1), and super-ohmic (s>1), as well as over a range of cutoff frequencies (omega(c)). In the sub-ohmic case, enhanced fidelity of BQT is observed. The dephasing effects on N <-> N qubit BQT are also explored, with our analysis uniquely demonstrating that the intrinsic efficiency (eta) can reach a maximum value of 50% while minimizing resource consumption and complexity.