P. Ciepielewski scite author profile

Various experimental data revealing large-area high-quality graphene films grown by the CVD method on Ge(001)/Si(001) substrates are presented. SEM images have shown that the structure of nano-facets is formed on the entire surface of Ge(001), which is covered by a graphene layer over the whole macroscopic sample surface of 1 cm(2). The hill-and-valley structures are positioned 90° to each other and run along the <100> direction. The hill height in relation to the valley measured by STM is about 10 nm. Raman measurements have shown that a uniform graphene monolayer covers the nano-facet structures on the Ge(001) surface. Raman spectroscopy has also proved that the grown graphene monolayer is characterized by small strain variations and minimal charge fluctuations. Atomically resolved STM images on the hills of the nanostructures on the Ge(001) surface have confirmed the presence of a graphene monolayer. In addition, the STS/CITS maps show that high-quality graphene has been obtained on such terraces. The subsequent coalescence of graphene domains has led to a relatively well-oriented large-area layer. This is confirmed by LEED measurements, which have indicated that two orientations are preferable in the grown large-area graphene monolayer. The presence of large-area coverage by graphene has been also confirmed by low temperature Hall measurements of a macroscopic sample, showing an n-type concentration of 9.3 × 10(12) cm(-2) and a mobility of 2500 cm(2) V(-1) s(-1). These important characteristic features of graphene indicate a high homogeneity of the layer grown on the large area Ge(001)/Si(001) substrates.

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Structural investigations of hydrogenated epitaxial graphene grown on 4H-SiC (0001)

Tokarczyk

Kowalski

Możdżonek

et al. 2013

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Structural investigations of hydrogenated epitaxial graphene grown on SiC(0001) are presented. It is shown that hydrogen plays a dual role. In addition to contributing to the well-known removal of the buffer layer, it goes between the graphene planes, resulting in an increase of the interlayer spacing to 3.6 Å–3.8 Å. It is explained by the intercalation of molecular hydrogen between carbon planes, which is followed by H2 dissociation, resulting in negatively charged hydrogen atoms trapped between the graphene layers, with some addition of covalent bonding to carbon atoms. Negatively charged hydrogen may be responsible for p-doping observed in hydrogenated multilayer graphene.

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Formation mechanism of graphene buffer layer on SiC(0 0 0 1)

Strupiński

Grodecki

Caban

et al. 2015

Carbon

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A W-band MMIC Resistive Mixer Based on Epitaxial Graphene FET

Habibpour

Strupiński

et al. 2017

IEEE Microw. Wireless Compon. Lett.

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The role of hydrogen in carbon incorporation and surface roughness of MOCVD-grown thin boron nitride

Caban

Teklińska

Gaca

et al. 2018

Journal of Crystal Growth

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P. Ciepielewski

Large-area high-quality graphene on Ge(001)/Si(001) substrates

Structural investigations of hydrogenated epitaxial graphene grown on 4H-SiC (0001)

Formation mechanism of graphene buffer layer on SiC(0 0 0 1)

A W-band MMIC Resistive Mixer Based on Epitaxial Graphene FET

The role of hydrogen in carbon incorporation and surface roughness of MOCVD-grown thin boron nitride

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