English

Minimal Energy Cost to Initialize a Quantum Bit with Tolerable Error

Quantum Physics 2022-09-15 v1 Statistical Mechanics

Abstract

Landauer's principle imposes a fundamental limit on the energy cost to perfectly initialize a classical bit, which is only reached under the ideal operation with infinite-long time. The question on the cost in the practical operation for a quantum bit (qubit) has been posted under the constraint by the finiteness of operation time. We discover a raise-up of energy cost by L2(ϵ)/τ\mathcal{L}^{2}(\epsilon)/\tau from the Landaeur's limit (kBTln2k_{B}T\ln2) for a finite-time τ\tau initialization with an error probability ϵ\epsilon. The thermodynamic length L(ϵ)\mathcal{L}(\epsilon) between the states before and after initializing in the parametric space increases monotonously as the error decreases. For example, in the constant dissipation coefficient (γ0\gamma_{0}) case, the minimal additional cost is 0.997kBT/(γ0τ)0.997k_{B}T/(\gamma_{0}\tau) for ϵ=1%\epsilon=1\% and 1.288kBT/(γ0τ)1.288k_{B}T/(\gamma_{0}\tau) for ϵ=0.1%\epsilon=0.1\%. Furthermore, the optimal protocol to reach the bound of minimal energy cost is proposed for the qubit initialization realized via a finite-time isothermal process.

Keywords

Cite

@article{arxiv.2112.07311,
  title  = {Minimal Energy Cost to Initialize a Quantum Bit with Tolerable Error},
  author = {Yu-Han Ma and Jin-Fu Chen and C. P. Sun and Hui Dong},
  journal= {arXiv preprint arXiv:2112.07311},
  year   = {2022}
}

Comments

5+5 pages, 3+3 figure, Comments are welcome

R2 v1 2026-06-24T08:16:34.747Z