Optical anisotropies of asymmetric double GaAs (001) quantum wells

Ruiz-Cigarrillo, O.; Lastras-Martı́nez, L. F.; Cerda‐Méndez, E. A.; Flores-Rangel, G.; Bravo-Velazquez, C. A.; Balderas‐Navarro, R. E.; Lastras‐Martínez, A.; Ulloa-Castillo, Nicolás A.; Biermann, K.; Santos, P. V.

doi:10.1103/physrevb.103.035309

Cited by 3 publications

(2 citation statements)

References 29 publications

(46 reference statements)

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“…For example, the anisotropy of the optical properties of an AlGaAs/ GaAs/AlGaAs double quantum well arising from the asymmetry of the heterostructure was recently observed. 9 Thus, optical reflection anisotropy spectroscopy enables effective detection of the response from several surface monolayers of bulk semiconductor materials and 2D structures, as well as other anisotropic media such as plasmonic nanostructures.…”

Section: Introductionmentioning

confidence: 99%

Fourier Transform Infrared Reflection Anisotropy Spectroscopy of Semiconductor Crystals and Structures: Development and Application in the Mid-Infrared

Firsov

Комков

2023

Appl Spectrosc

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A new method of reflection anisotropy spectroscopy (RAS) with increased mid-IR efficiency owing to the use of a Fourier-transform infrared (FT-IR) spectrometer has been developed. An optical setup was implemented using a photoelastic modulator (PEM) to modulate the direction of linear polarization of the probe beam originating from the Michelson interferometer. An original measurement algorithm was proposed to eliminate the influence of spectral inhomogeneity of the PEM efficiency on the obtained spectra via appropriate calibration. It was shown that to preserve the sign of the RAS signal, it is necessary to use a specialized procedure for phase correction of the interferogram registered by the FT-IR spectrometer. In the visible range, good agreement was confirmed between the obtained reflection anisotropy (RA) spectra of a semiconductor crystal and the results of independent measurements using a conventional diffraction grating spectrometer-based setup. The RA spectrum of a III-V semiconductor heterostructure in the mid-infrared range (λ up to 8 µm) is demonstrated. Application of the developed FT-IR RAS method to layered black phosphorus has enabled characterization of anisotropic interband transitions in a graphene-like semiconductor crystal.

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Section: Introductionmentioning

confidence: 99%

Fourier Transform Infrared Reflection Anisotropy Spectroscopy of Semiconductor Crystals and Structures: Development and Application in the Mid-Infrared

Firsov

Комков

2023

Appl Spectrosc

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“…In the case of III/V semiconductors RIE-RAS (in situ and in real time) monitors the erosion of the surface and can easily detect the interfaces between adjacent layers, for example, due to electric dipoles on the surface or strain. The latter might even stem from a layer just a few nanometers thick [13,[15][16][17].…”

Section: Introduction 1general Remarksmentioning

confidence: 99%

Doped or Quantum-Dot Layers as In Situ Etch-Stop Indicators for III/V Semiconductor Reactive Ion Etching (RIE) Using Reflectance Anisotropy Spectroscopy (RAS)

et al. 2021

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Reflectance anisotropy spectroscopy (RAS), which was originally invented to monitor epitaxial growth, can—as we have previously shown—also be used to monitor the reactive ion etching of III/V semiconductor samples in situ and in real time, as long as the etching rate is not too high and the abrasion at the etch front is not totally chaotic. Moreover, we have proven that—using RAS equipment and optical Fabry‒Perot oscillations due to the ever-shrinking thickness of the uppermost etched layer—the in situ etch-depth resolution can be as good as ±0.8 nm, employing a Vernier-scale type measurement and evaluation procedure. Nominally, this amounts to ±1.3 lattice constants in our exemplary material system, AlGaAsSb, on a GaAs or GaSb substrate. In this contribution, we show that resolutions of about ±5.6 nm can be reliably achieved without a Vernier scale protocol by employing thin doped layers or sharp interfaces between differently doped layers or quantum-dot (QD) layers as etch-stop indicators. These indicator layers can either be added to the device layer design on purpose or be part of it incidentally due to the functionality of the device. For typical etch rates in the range of 0.7 to 1.3 nm/s (that is, about 40 to 80 nm/min), the RAS spectrum will show a distinct change even for very thin indicator layers, which allows for the precise termination of the etch run.

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