Atomic-Scale Insights into Semiconductor Heterostructures: From Experimental Three-Dimensional Analysis of the Interface to a Generalized Theory of Interfacial Roughness Scattering

Grange, Thomas; Mukherjee, Samik; Capellini, Giovanni; Montanari, Michele; Persichetti, Luca; Gaspare, L. Di; Birner, Stefan; Attiaoui, Anis; Moutanabbir, Oussama; Virgilio, Michele; Seta, M. De

doi:10.1103/physrevapplied.13.044062

Cited by 39 publications

(35 citation statements)

References 36 publications

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“…1c,d), STEM shows sharp and abrupt interfaces, with a broadening due to SiGe intermixing in the order of 0.8 nm [21]. The quality of the heterointerfaces is confirmed by the low value of the rootmean-square interface roughness which was estimated to be 0.18 nm by atomic probe tomography measurements performed on the same set of samples [30]. The thickness of wells and barriers reported in Table 1 was measured by energy-dispersive x-ray spectroscopy (EDX), while the periodicity of the MQW stack D SL was obtained by XRD.…”

Section: Methodsmentioning

confidence: 81%

Intersubband Transition Engineering in the Conduction Band of Asymmetric Coupled Ge/SiGe Quantum Wells

et al. 2020

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n-type Ge/SiGe asymmetric-coupled quantum wells represent the building block of a variety of nanoscale quantum devices, including recently proposed designs for a silicon-based THz quantum cascade laser. In this paper, we combine structural and spectroscopic experiments on 20module superstructures, each featuring two Ge wells coupled through a Ge-rich tunnel barrier, as a function of the geometry parameters of the design and the P dopant concentration. Through the comparison of THz spectroscopic data with numerical calculations of intersubband optical absorption resonances, we demonstrated that it is possible to tune by design the energy and the spatial overlap of quantum confined subbands in the conduction band of the heterostructures. The high structural/interface quality of the samples and the control achieved on subband hybridization are the promising starting point towards a working electrically pumped light-emitting device.

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Section: Methodsmentioning

confidence: 81%

Intersubband Transition Engineering in the Conduction Band of Asymmetric Coupled Ge/SiGe Quantum Wells

et al. 2020

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“…Moreover, to accurately describe the scattering rate associated to IFR, selected samples have been investigated also by means of atom probe tomography 5 . In this way, we were able to precisely measure the root-mean square (rms) amplitude Δ (0.18 nm) and the in-plane correlation length Λ// (6.9 nm) associated to the interface roughness.…”

Section: Experimental and Theoretical Methodsmentioning

confidence: 99%

“…Due to a more mature epitaxy technology, carrier scattering in low dimensional systems has been investigated mainly focusing on III-V based structures 2,3 . However, in the last two decades, advances in group-IV epitaxy have made possible to grow SiGe multilayer systems with high crystal quality [4][5][6][7][8] ; consequently this class of materials is attracting increasing research efforts, mainly motivated by its prompt integrability with the mainstream CMOS standard. In particular, in the last ten years, SiGe Ge-rich structures have been actively investigated, and applications have been proposed in different contexts as for instance quantum computing [8][9][10] , Si-based photonics [11][12][13] , high mobility transistors 14,15 , and thermoelectricity 16,17 .…”

Section: Introductionmentioning

confidence: 99%

Electron-phonon coupling in n -type Ge two-dimensional systems

et al. 2020

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Electron-optical phonon interaction is the dominant energy-loss mechanism in low dimensional Ge/SiGe heterostructures and represents a key parameter for the design and realization of electronic and optoelectronic devices based on this material system compatible with the mainstream Si-CMOS technology. Here we investigate the intersubband relaxation dynamics of n-type Ge/SiGe multi-quantum wells with different symmetry and design by means of single-color pump-probe spectroscopy. By comparing the experimental differential transmittance data as a function of the pump-probe delay with numerical calculations based on an energy-balance rate equation model, we could quantify an effective value for the optical phonon deformation potential describing the electron-phonon coupling in 2D Ge-based systems. We found non-radiative relaxation times longer than 20 ps even in samples having intersubband energy separations larger than the optical phonon energy, evidencing the presence of a less effective electron-phonon coupling with respect to what estimated in bulk Ge.

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“…In the following, the ISB non-radiative lifetimes have been calculated from a full-subband population dynamics model [42] based on equations similar to those that lead to the results of Figure 3 but are adapted to the specific ACQW samples and consider the optical pumping conditions of the present work. In particular, to correctly account for inter-and intra-subband particle and energy fluxes in ACQWs, we included here, in addition to electron-phonon scattering, the contribution of the elastic scattering channels due to interface roughness (assuming an interface roughness amplitude of 0.2 nm with correlation length of 7.0 nm [12]) and to ionized impurity. In fact, the latter is expected to play a role at the high doping levels required for QFLs.…”

Section: Numerical Simulations Of Subband Population Dynamicsmentioning

confidence: 99%

“…Since an electrically pumped Ge/SiGe QCL has been designed but not realized yet [9][10][11], optically pumped devices may offer an easier experimental test bench to assess the performances of models with out-of-equilibrium intersubband (ISB) population dynamics. For optically pumped lasers, electrical contacts are not required, thus eliminating most of the device processing steps and related difficulties [12], and besides, much simpler active layer QW stacks are needed compared to QCLs. The basic structure for an optically pumped QW emitter consists of two asymmetric (i.e., of different thickness and/or composition) wells coupled through a thin tunnelling barrier (asymmetric coupled QWs, ACQWs) [13].…”

Section: Introductionmentioning

confidence: 99%

Electron Population Dynamics in Optically Pumped Asymmetric Coupled Ge/SiGe Quantum Wells: Experiment and Models

et al. 2019

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n-type doped Ge quantum wells with SiGe barriers represent a promising heterostructure system for the development of radiation emitters in the terahertz range such as electrically pumped quantum cascade lasers and optically pumped quantum fountain lasers. The nonpolar lattice of Ge and SiGe provides electron–phonon scattering rates that are one order of magnitude lower than polar GaAs. We have developed a self-consistent numerical energy-balance model based on a rate equation approach which includes inelastic and elastic inter- and intra-subband scattering events and takes into account a realistic two-dimensional electron gas distribution in all the subband states of the Ge/SiGe quantum wells by considering subband-dependent electronic temperatures and chemical potentials. This full-subband model is compared here to the standard discrete-energy-level model, in which the material parameters are limited to few input values (scattering rates and radiative cross sections). To provide an experimental case study, we have epitaxially grown samples consisting of two asymmetric coupled quantum wells forming a three-level system, which we optically pump with a free electron laser. The benchmark quantity selected for model testing purposes is the saturation intensity at the 1→3 intersubband transition. The numerical quantum model prediction is in reasonable agreement with the experiments and therefore outperforms the discrete-energy-level analytical model, of which the prediction of the saturation intensity is off by a factor 3.

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Atomic-Scale Insights into Semiconductor Heterostructures: From Experimental Three-Dimensional Analysis of the Interface to a Generalized Theory of Interfacial Roughness Scattering

Cited by 39 publications

References 36 publications

Intersubband Transition Engineering in the Conduction Band of Asymmetric Coupled Ge/SiGe Quantum Wells

Intersubband Transition Engineering in the Conduction Band of Asymmetric Coupled Ge/SiGe Quantum Wells

Electron-phonon coupling in n -type Ge two-dimensional systems

Electron Population Dynamics in Optically Pumped Asymmetric Coupled Ge/SiGe Quantum Wells: Experiment and Models

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