K. Zekentes scite author profile

The results of magnetoconductivity measurements in GaInAs quantum wells are presented. The observed magnetoconductivity appears due to the quantum interference, which lead to the weak localization effect. It is established that the details of the weak localization are controlled by the spin splitting of electron spectra. A theory is developed which takes into account both linear and cubic in electron wave vector terms in spin splitting, which arise due to the lack of inversion center in the crystal, as well as the linear terms which appear when the well itself is asymmetric. It is established that, unlike spin relaxation rate, contributions of different terms into magnetoconductivity are not additive. It is demonstrated that in the interval of electron densities under investigation ((0.98 − 1.85)·1012 cm −2 ) all three contribution are comparable and have to be taken into account to achieve a good agreement between the theory and experiment. The results obtained from comparison of the experiment and the theory have allowed us to determine what mechanisms dominate the spin relaxation in quantum wells and to improve the accuracy of determination of spin splitting parameters in A3B5 crystals and 2D structures. 73.20.Fz,73.70.Jt,71.20.Ej,72.20.My

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SiC nanowires: material and devices

Zekentes¹,

Rogdakis²

2011

J. Phys. D: Appl. Phys.

184

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Abstract. SiC nanowires are of high interest since they combine the physical properties of SiC with those induced by their low dimensionality. For this reason, a large number of scientific studies have been dedicated to their fabrication and characterization as well as to their application in devices. SiC nanowires growth involving different growth mechanisms and configurations was the main theme for the large majority of these studies. Various physical characterization methods have been employed for evaluating SiC nanowire quality. Very low diameter (<10 nm) nanowires as well as nanowires free of planar defects have not been demonstrated and these are some of the main challenges. Another issue is the high unintentional doping of the nanowires that does not allow the demonstration of high performance field effect transistors using SiC nanowires as channel material. On the other hand, the grown nanowires are suitable for field emission applications and to be used as reinforcing material in composite structures as well as for increasing the hydrophobicity of Si surfaces. All these aspects are examined in detail in the different sections of the present paper.

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3C-Silicon Carbide Nanowire FET: An Experimental and Theoretical Approach

Rogdakis

Lee

Bescond

et al. 2008

IEEE Trans. Electron Devices

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Progress in SiC nanowire field-effect-transistors for integrated circuits and sensing applications

Zekentes

Choi

Stambouli

et al. 2022

Microelectronic Engineering

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K. Zekentes

Weak antilocalization and spin precession in quantum wells

SiC nanowires: material and devices

3C-Silicon Carbide Nanowire FET: An Experimental and Theoretical Approach

Progress in SiC nanowire field-effect-transistors for integrated circuits and sensing applications

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