Philipp Schroth scite author profile

In III-V nanowires the energetic barriers for nucleation in the zinc blende or wurtzite arrangement are typically of a similar order of magnitude. As a result, both arrangements can occur in a single wire. Here, we investigate the evolution of this polytypism in self-catalyzed GaAs nanowires on Si(111) grown by molecular beam epitaxy with time-resolved in situ x-ray diffraction. We interpret our data in the framework of a height dependent Markov model for the stacking in the nanowires. In this way, we extract the mean sizes of faultless wurtzite and zinc blende segments-a key parameter of polytypic nanowires-and their temporal evolution during growth. Thereby, we infer quantitative information on the differences of the nucleation barriers including their evolution without requiring a model of the nucleus.

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Radial Growth of Self-Catalyzed GaAs Nanowires and the Evolution of the Liquid Ga-Droplet Studied by Time-Resolved in Situ X-ray Diffraction

Schroth

Jakob

Feigl

et al. 2017

Nano Lett.

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We report on a growth study of self-catalyzed GaAs nanowires based on time-resolved in situ X-ray structure characterization during molecular-beam-epitaxy in combination with ex situ scanning-electron-microscopy. We reveal the evolution of nanowire radius and polytypism and distinguish radial growth processes responsible for tapering and side-wall growth. We interpret our results using a model for diameter self-stabilization processes during growth of self-catalyzed GaAs nanowires including the shape of the liquid Ga-droplet and its evolution during growth.

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In situ x-ray analysis of misfit strain and curvature of bent polytypic GaAs–In _x Ga_1−xAs core–shell nanowires

et al. 2021

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Misfit strain in core–shell nanowires can be elastically released by nanowire bending in case of asymmetric shell growth around the nanowire core. In this work, we investigate the bending of GaAs nanowires during the asymmetric overgrowth by an In x Ga1−x As shell caused by avoiding substrate rotation. We observe that the nanowire bending direction depends on the nature of the substrate’s oxide layer, demonstrated by Si substrates covered by native and thermal oxide layers. Further, we follow the bending evolution by time-resolved in situ x-ray diffraction measurements during the deposition of the asymmetric shell. The XRD measurements give insight into the temporal development of the strain as well as the bending evolution in the core–shell nanowire.

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A portable molecular beam epitaxy system for in situ x-ray investigations at synchrotron beamlines

Slobodskyy

Schroth

Grigoriev

et al. 2012

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A portable synchrotron molecular beam epitaxy (MBE) system is designed and applied for in situ investigations. The growth chamber is equipped with all the standard MBE components such as effusion cells with shutters, main shutter, cooling shroud, manipulator, reflection high energy electron diffraction setup, and pressure gauges. The characteristic feature of the system is the beryllium windows which are used for in situ x-ray measurements. An UHV sample transfer case allows in vacuo transfer of samples prepared elsewhere. We describe the system design and demonstrate its performance by investigating the annealing process of buried InGaAs self-organized quantum dots.

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Philipp Schroth

Evolution of Polytypism in GaAs Nanowires during Growth Revealed by Time-Resolvedin situx-ray Diffraction

Radial Growth of Self-Catalyzed GaAs Nanowires and the Evolution of the Liquid Ga-Droplet Studied by Time-Resolved in Situ X-ray Diffraction

In situ x-ray analysis of misfit strain and curvature of bent polytypic GaAs–In _x Ga_1−xAs core–shell nanowires

A portable molecular beam epitaxy system for in situ x-ray investigations at synchrotron beamlines

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Resources

About

Philipp Schroth

Evolution of Polytypism in GaAs Nanowires during Growth Revealed by Time-Resolvedin situx-ray Diffraction

Radial Growth of Self-Catalyzed GaAs Nanowires and the Evolution of the Liquid Ga-Droplet Studied by Time-Resolved in Situ X-ray Diffraction

In situ x-ray analysis of misfit strain and curvature of bent polytypic GaAs–In x Ga1−x As core–shell nanowires

A portable molecular beam epitaxy system for in situ x-ray investigations at synchrotron beamlines

Contact Info

Product

Resources

About

In situ x-ray analysis of misfit strain and curvature of bent polytypic GaAs–In _x Ga_1−xAs core–shell nanowires