Quantum speed limit time for topological qubit influenced by fermionic and bosonic environment

TL;DR

This paper investigates how fermionic and bosonic environments affect the quantum speed limit time of topological qubits, revealing that environment type and magnetic fields significantly influence quantum evolution rates.

Contribution

It provides a detailed analysis of quantum speed limit times for topological qubits under various environmental conditions and magnetic fields, considering Ohmic spectral densities.

Findings

Super-Ohmic environments lead to a constant quantum speed limit time at high Ohmic parameters.

Increasing magnetic field magnitude decreases the quantum speed limit time.

Quantum evolution rate stabilizes for super-Ohmic environments with high Ohmic parameters.

Abstract

Quantum theory sets a limit on the minimum time required to transform from an initial state to a target state. It is known as quantum speed limit time. quantum speed limit time can be used to determine the rate of quantum evolution for closed and open quantum systems. Given that in the real world we are dealing with open quantum systems, the study of quantum speed limit time for such systems has particular importance. In this work we consider the topological qubit realized by two Majorana modes. We consider the case in which the topological qubit is influenced by fermionic and bosonic environment. Fermionic and bosonic environments are assumed to have Ohmic-like spectral density. The quantum speed limit time is investigated for various environment with different Ohmic parameter. It is observed that for super-Ohmic environment with increasing Ohmic parameter the quantum speed limit time gradually reaches to a constant value and thus the speed of evolution reaches to a uniform value. The effects of external magnetic field on the evolution rate are also studied. It is observed that with increasing magnitude of magnetic field, the quantum speed limit time decreases