Controlling the optical properties of a laser pulse at λ = 1.55μm in InGaAs\InP double coupled quantum well nanostructure

Jalil Shiri; Abdollah Malakzadeh

doi:10.1186/s41476-017-0047-7

All issues

Volume 13 / No 1 (2017)

J. Eur. Opt. Soc.-Rapid Publ., 13 1 (2017) 19

Abstract

Open Access

Issue		J. Eur. Opt. Soc.-Rapid Publ. Volume 13, Number 1, 2017


Article Number		19
Number of page(s)		7
DOI		https://doi.org/10.1186/s41476-017-0047-7
Published online		14 August 2017

J. Eur. Opt. Soc.-Rapid Publ. (2017) 13: 19

Research

Controlling the optical properties of a laser pulse at λ = 1.55μm in InGaAs\InP double coupled quantum well nanostructure

Jalil Shiri¹^a and Abdollah Malakzadeh²

¹ Young Researchers and Elite Club, North Tehran Branch, Islamic Azad University, Tehran, Iran
² Centre for laser and optics, Basic Sciences Department, Imam Hussein University, Tehran, Iran

^a jalil.shiri@chmail.ir

Received: 4 May 2017
Accepted: 28 July 2017

Abstract

Background: The transient and steady-state behaviour of the absorption and the dispersion of a probe field propagating at λ = 1.55μm through an InGaAs\InP double coupled quantum well are studied. The effect of terahertz signal excitation, electron tunnelling and incoherent pumping on the optical properties of the probe field is discussed.

Methods: The linear dynamical properties of the double coupled quantum well by means of perturbation theory and density matrix method are discussed.

Results: We show that the group velocity of a light pulse can be controlled from superluminal to subluminal or vice versa by controlling the rates of incoherent pumping field, terahertz signal and tunnelling between the quantum wells. The required switching time is calculated and we find it between 3 to 15 ps.

Conclusions: In the terahertz (30 ~ 300 μm or 1 ~ 10THz) intersubband transition, the incoming photon energy is (4 ~ 41mev) and maybe in the order of electron thermal broadening (KT ~ 6 meV-25 meV for 77 K -300 K). Therefore in the conventional structure, the incoming photon can directly excite the ground state electrons to higher energy levels. It is shown that the absorption and the dispersion of the probe field can be controlled by the intensity of terahertz signal and incoherent pumping field.

Key words: Electro-optical switching / Dispersion and absorption / Group velocity / Terahertz signal / Tunnelling effects / Incoherent pumping field

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