Abstract
Carrier localization effects in III-N heterostructures are often studied in the frame of modified continuum-based models utilizing a single-band effective mass approximation. However, there exists no comparison between the results of a modified continuum model and atomistic calculations on the same underlying disordered energy landscape. We present a theoretical framework that establishes a connection between atomistic tight-binding theory and continuum-based electronic structure models, here a single-band effective mass approximation, and provide such a comparison for the electronic structure of (In,Ga)N quantum wells. In our approach, in principle, the effective masses are the only adjustable parameters since the confinement energy landscape is directly obtained from tight-binding theory. We find that the electronic structure calculated within effective mass approximation and the tight-binding model differ noticeably. However, at least in terms of energy eigenvalues, an improved agreement between the two methods can be achieved by adjusting the band offsets in the continuum model, enabling, therefore, a recipe for constructing a modified continuum model that gives a reasonable approximation of the tight-binding energies. Carrier localization characteristics for energetically low lying, strongly localized states differ, however, significantly from those obtained using the tight-binding model. For energetically higher lying, more delocalized states, good agreement may be achieved. Therefore, the atomistically motivated continuum-based single-band effective mass model established provides a good, computationally efficient alternative to fully atomistic investigations, at least at when targeting questions related to higher temperatures and carrier densities in (In,Ga)N systems.
Highlights
In the past two decades, III-N-based semiconductors have attracted significant research interest given their potential for a variety of different applications
Given that single-band effective mass models are often applied to study carrier localization effects in (In,Ga)N systems, any problem arising from the fact that a strongly fluctuating energy landscape presents in general a challenge for continuum-based models, should be revealed by the analysis presented in this work
We present the findings on the electronic structure of InxGa1ÀxN single quantum wells (QWs) obtained within TB and continuumbased calculations
Summary
In the past two decades, III-N-based semiconductors have attracted significant research interest given their potential for a variety of different applications. To target carrier localization effects in a such a 3D description, a variety of different theoretical approaches has been applied in the literature These range from fully atomistic calculations[12,16] to modified continuum-based models.[10,11,17,18,19,20] While atomistic modeling has been successfully applied to describe whole devices[21,22] as well as the influence of alloy fluctuations on the electronic properties of semiconductor heterostructures,[13,23] their application generates a huge computational effort, depending on the numbers of atoms involved. In industry focused device design activities, the huge computational effort of full atomistic device calculations is often not a viable route
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