Abstract
The paper reports on the charge transport in the sandwich-like graphene / Co nanoparticles / graphene structure (G/CoNPs/G). It is fabricated by combining the electrochemical deposition of Co nanoparticles onto a single layer CVD graphene and their capping with another graphene layer. The isolated semi-spherical, surface oxidized Co NPs of 250 nm in diameter serve as a support for the top graphene layer and provide its suspended state confirmed by atomic force microscopy revealing periodic ripples on its surface. A high optical transparency of 92.4% is found for the G/CoNPs/G sandwich. The observed twofold reduction in the sheet resistance with a ∼ 1.5 times increase in the positive magnetoresistive effect for G/CoNPs/G compared to the pristine graphene is attributed to the suppression of carrier scattering due to the substrate. From the Hall effect measurements, a predominant role of the top graphene layer in the charge transport in G/CoNPs/G is established, with a significantly increased carrier mobility µ∼1800 cm2/(V·s). An elastic intervalley scattering length estimated from the magnetoresistance results is found to be three times increased in G/CoNPs/G, indicating that the top graphene layer is almost unaffected by the substrate. The proposed technology looks promising for possible optoelectronic and magneto-optical applications.
Highlights
Transparent conductive films (TCFs) play an exceptional role in many modern applications that use liquid crystal displays, organic light-emitting diodes (OLED) or photovoltaic cells
A new composite sandwich-like Graphene / Co nanoparticles / Graphene structure (G/CoNPs/G) was obtained on SiO2/Si or glass substrate by transferring a single layer of chemical vapor deposition (CVD) graphene onto another single layer CVD graphene modified with Co nanoparticles (NPs)
As it was estimated in our previous work, metallic cores of Co NPs are covered with insulating CoO oxide shells, which prevent the electrical contact between the NPs and top graphene layer
Summary
Transparent conductive films (TCFs) play an exceptional role in many modern applications that use liquid crystal displays, organic light-emitting diodes (OLED) or photovoltaic cells. Possessing an optimal set of properties (high optical transparency exceeding 90% and electrical conductivity of 10–30 Ohm/square), Indium Tin Oxide (ITO) has become the market standard for most of these applications [1]. Considering the trends in indium demand, levels of its production and recycling, in 20–30 years the existing supply may hardly meet the demand. At this point, the price will rise [2]. ITO is a delicate crystalline material that excludes its use as a flexible TCF. Fabrication of flexible TCFs is the primary task for producing flexible OLED displays. The most promising materials in this field are carbon nanotubes [3,4], metal nanowires [5], conducting polymers [6,7], and graphene [1]
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