A. K. Tyagi scite author profile

We present an extensive study on electrical spectroscopy of graphene ribbons and edges of highly oriented pyrolytic graphite (HOPG) using atomic force microscope (AFM). We have addressed in the present study two main issues, (1) How does the electrical property of the graphite (graphene) sheet change when the graphite layer is displaced by shear forces? and (2) How does the electrical property of the graphite sheet change across a step edge? While addressing these two issues we observed, (1) variation of conductance among the graphite ribbons on the surface of HOPG. The top layer always exhibits more conductance than the lower layers, (2) two different monolayer ribbons on the same sheet of graphite shows different conductance, (3) certain ribbon/sheet edges show sharp rise in current, (4) certain ribbons/sheets on the same edge shows both presence and absense of the sharp rise in the current, (5) some lower layers at the interface near a step edge shows a strange dip in the current/conductance (depletion of charge). We discuss possible reasons for such rich conducting landscape on the surface of graphite.

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Enhanced conductivity in graphene layers and at their edges

Banerjee

Sardar

Gayathri

et al. 2006

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We have observed that the conductivity of graphene sheets is higher whenever they are loosely bound to the underlying bulk graphite. We also observe that certain edges of the graphene layers show sharp rise in current when biased, indicating enhanced electronic density of states spatially localized near those edges. In certain edges, we do not observe this phenomenon. These two observations, i.e., enhancement of conductivity of loosely bound layers and sharp rise in current at the edges are discussed with possible reasons and invoking recent theoretical predictions.

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Studies on high iron content in water resources of Moradabad district (UP), India

et al. 2017

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Nanocrystalline and metastable phase formation in vacuum thermal decomposition of calcium carbonate

et al. 2000

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A. K. Tyagi

Enhanced oxidation of the 9%Cr steel P91 in water vapour containing environments

Conductivity landscape of highly oriented pyrolytic graphite surfaces containing ribbons and edges

Enhanced conductivity in graphene layers and at their edges

Studies on high iron content in water resources of Moradabad district (UP), India

Nanocrystalline and metastable phase formation in vacuum thermal decomposition of calcium carbonate

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