T. Grabolla scite author profile

One of the limiting factors of graphene integration into electronic, photonic, or sensing devices is the unavailability of large-scale graphene directly grown on the isolators. Therefore, it is necessary to transfer graphene from the donor growth wafers onto the isolating target wafers. In the present research, graphene was transferred from the chemical vapor deposited 200 mm Germanium/Silicon (Ge/Si) wafers onto isolating (SiO2/Si and Si3N4/Si) wafers by electrochemical delamination procedure, employing poly(methylmethacrylate) as an intermediate support layer. In order to influence the adhesion properties of graphene, the wettability properties of the target substrates were investigated in this study. To increase the adhesion of the graphene on the isolating surfaces, they were pre-treated with oxygen plasma prior the transfer process of graphene. The wetting contact angle measurements revealed the increase of the hydrophilicity after surface interaction with oxygen plasma, leading to improved adhesion of the graphene on 200 mm target wafers and possible proof-of-concept development of graphene-based devices in standard Si technologies.

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T. Grabolla

SiGe HBT technology with f<inf>T</inf>/f<inf>max</inf> of 300GHz/500GHz and 2.0 ps CML gate delay

SiGe HBT with fx/fmax of 505 GHz/720 GHz

A 0.13 $\mu{\hbox {m}}$ SiGe BiCMOS Technology Featuring f$_{T} $/f$_{\max}$ of 240/330 GHz and Gate Delays Below 3 ps

Novel collector design for high-speed SiGe:C HBTs

Influence of plasma treatment on SiO2/Si and Si3N4/Si substrates for large-scale transfer of graphene

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