1. Introduction
Active mode locking (AML) via modulation of the injection current or bias is a standard technique employed for the generation of ultrashort pulses in electrically pumped lasers. Quantum cascade lasers (QCLs), as sources of radiation in the mid- and far-infrared portions of the electromagnetic spectrum, have turned out to be exceedingly difficult to actively mode lock, due to the inherently short gain recovery time of these kind of devices [1]. In the mid-infrared, both theoretical and experimental results have shown that this obstacle can be overcome by modulating only a short, electrically isolated section of the QCL cavity [1, 2], which could lead to generation of ultrashort picosecond pulses. For terahertz (THz) QCLs, most recently successful active mode locking of an LO-phonon THz-QCL was reported [3], and pulses as short as 11 ps were detected. Furthermore, in the same work, the importance of correct coupling between the propagating gigahertz (GHz) and terahertz fields was explicitly outlined and the role of the wave-guiding structure in the modulation process emphasized. Here, we present a theoretical model based on the Maxwell-Bloch and the transmission line equations, suitable for investigation of such systems.
2. Theoretical model
We propose a simulation approach for the analysis of electron transport in metal-metal waveguide terahertz QCLs, based on the Maxwell-Bloch and the transmission line equations. A schematic diagram of a typical device, as well as an equivalent circuit representation of a differential section of the waveguide, are presented in Fig. 1a and 1b, respectively.
In our model, where π§ is assumed as the growth direction and π₯ as the propagation direction, we treat the metal-metal waveguide as a parallel plate transmission line with capacitance and inductance per unit length, πΆβ²and πΏβ², respectively. Sandwiched between the metallic electrodes lies the QCLβs active region (AR), which we model within a density matrix formalism, i.e. Bloch equations, coupled to the optical field via the classical Maxwellβs equations. The transmission line equations are used to resolve the bias voltage π£(π₯,π‘) in time and space along the length of the cavity l, as a function of the longitudinal current π(π₯,π‘) and the QCLβs current density π½(π₯,π‘). At each time step of our simulation, we interpolate all bias dependent quantities, which enter the density matrix, from a set of precalculated values, obtained with the aid of our SchrΓΆdinger-Poisson solver and our ensemble Monte
ππ
ππ
π
Fig. 1. a Schematic diagram of a metal-metal waveguide QCL. A longitudinal current i(x,t) is assumed to flow along the metallic electrodes, with a corresponding voltage drop v(x,t) and current density J(x,t) across the QCLβs active region. b An equivalent circuit representation of a differential section of the waveguide, treated as a parallel plate transmission line with capacitance per unit length πΆβ² and inductance per unit length πΏβ².
x
z
y
a
π½(π₯,π‘),π£(π₯,π‘)
π(π₯,π‘)
π½(π₯,π‘)
πΆβ
πΏβ
π£(π₯,π‘)
π(π₯,π‘)
π₯
b
Ξπ₯
π0
Carlo (EMC) simulation code [4]. In this way, we acquire a comprehensive model for the investigation of dynamic electro-optical phenomena, which goes beyond the standard Maxwell-Bloch formalism employed in Refs. [1, 2] and might explain some of the coupling effects suggested in Refs. [3, 5]
3. Results
As a proof of concept, we tested our modelling approach to simulate active mode locking of the device in Ref. [3]. The active mode locking was implemented as a sinusoidal modulation of an externally applied voltage ππ , connected via a ππ =50 Ξ© impedance bonding wire to the left edge of the waveguide. In order to investigate the importance of THz and GHz refractive index matching for successful mode locking [3], we considered three separate simulation scenarios. Setting the THz central frequencyβs refractive index at πππ»π§=3.6 and the GHz index at ππΊπ»π§=4.0, we modulated ππ sinusoidally, i.e. ππ (π‘)=ππ π·πΆ[1+πΓsin(2πππππt)]. When modulation was turned off, Fig. 2a-b, the laser produced a multimode spectrum with equidistant longitudinal modes separated by the free spectral range of ππ
πβ13.46 GHz. Alternatively, when the input voltage was modulated at the GHz wave round trip frequency ππΊπ»π§β12.49 πΊπ»π§, Fig. 2c-d, the simulation produced rich spectral dynamics which we believe are the result of the competition between the propagating THz and GHz waves, i.e. the so called pulling of ππ
π [5]. Lastly, Fig. 2e-f depicts simulation results when ππ was modulated completely off-resonance. From the resulting spectra as well as beatnote signal, we deduce that the round trip frequency of the THz wave is only weakly perturbed by the voltage modulation and hence at this regime no locking of the round trip frequency is possible.
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