Article citationsMore>>
Olver, F.W.J., Olde Daalhuis, A.B., Lozier, D.W., Schneider, B.I., Boisvert, R.F., Clark, C.W., Miller, B.R., Saunders, B.V., Cohl, H.S. and McClain, M.A. (2020) NIST Digital Library of Mathematical Functinos, Release 1.0.28 of 2020-09-15.
http://dlmf.nist.gov
has been cited by the following article:
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TITLE:
Stochastic Simulation of Emission Spectra and Classical Photon Statistics of Quantum Dot Superluminescent Diodes
AUTHORS:
Kai Niklas Hansmann, Reinhold Walser
KEYWORDS:
Stochastic Simulation, Quantum Dot, Superluminescent Diode
JOURNAL NAME:
Journal of Modern Physics,
Vol.12 No.1,
January
8,
2021
ABSTRACT: We present a stochastic procedure to investigate the correlation spectra of quantum dot superluminescent diodes. The classical electric field of a diode is formed by a polychromatic superposition of many independent stochastic oscillators. Assuming fields with individual carrier frequencies, Lorentzian linewidths and amplitudes we can form any relevant experimental spectrum using a least square fit. This is illustrated for Gaussian and Lorentzian spectra, Voigt profiles and box shapes. Eventually, the procedure is applied to an experimental spectrum of a quantum dot superluminescent diode which determines the first- and second-order temporal correlation functions of the emission. We find good agreement with the experimental data and a quantized treatment. Thus, a superposition of independent stochastic oscillators represents the first- and second-order correlation properties of broadband light emitted by quantum dot superluminescent diodes.
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