English

Memory Effects in Spontaneous Emission Processes

Quantum Physics 2013-05-30 v1 Mesoscale and Nanoscale Physics

Abstract

We consider a quantum-mechanical analysis of spontaneous emission in terms of an effective two-level system with a vacuum decay rate Γ0\Gamma_0 and transition angular frequency ωA\omega_A. Our analysis is in principle exact, even though presented as a numerical solution of the time-evolution including memory effects. The results so obtained are confronted with previous discussions in the literature. In terms of the {\it dimensionless} lifetime τ=tΓ0\tau = t\Gamma_0 of spontaneous emission, we obtain deviations from exponential decay of the form O(1/τ){\cal O} (1/\tau) for the decay amplitude as well as the previously obtained asymptotic behaviors of the form O(1/τ2){\cal O} (1/\tau^2) or O(1/τln2τ){\cal O} (1/\tau \ln^2\tau) for τ1\tau \gg 1 . The actual asymptotic behavior depends on the adopted regularization procedure as well as on the physical parameters at hand. We show that for any reasonable range of τ\tau and for a sufficiently large value of the required angular frequency cut-off ωc\omega_c of the electro-magnetic fluctuations, i.e. ωcωA\omega_c \gg \omega_A, one obtains either a O(1/τ){\cal O} (1/\tau) or a O(1/τ2){\cal O} (1/\tau^2) dependence. In the presence of physical boundaries, which can change the decay rate with many orders of magnitude, the conclusions remains the same after a suitable rescaling of parameters.

Keywords

Cite

@article{arxiv.1209.1401,
  title  = {Memory Effects in Spontaneous Emission Processes},
  author = {Arne L. Grimsmo and Asle H. Vaskinn and Per K. Rekdal and Bo-Sture K. Skagerstam},
  journal= {arXiv preprint arXiv:1209.1401},
  year   = {2013}
}

Comments

13 pages, 5 figures and 46 references

R2 v1 2026-06-21T22:01:10.043Z