Graphene Conductance Uniformity Mapping

Buron, J.; Petersen, Dirch Hjorth; Bøggild, Peter; Cooke, David G.; Hilke, Michael; Sun, Jie; Whiteway, Eric; Nielsen, Peter Brønnum; Hansen, Ole; Yurgens, A.; Jepsen, Peter Uhd

doi:10.1021/nl301551a

Cited by 159 publications

(192 citation statements)

References 66 publications

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“…14 The ambiguity in these findings arose from a lack of knowledge of the precise domain/grain morphology for the samples measured. While there are recent studies that produced maps of the electronic properties of graphene GBs using scanning tunneling microscope (STM) 21 and of graphene conductance using micro four-point probe and non-contact terahertz time-domain spectroscopy measurements, 22 a one-to-one correspondence between defect structures and transport properties is still lacking. Indeed, because of the large length-scale difference between the atomic-scale defect structures and transport functions whose variations range from atomicscale to mesoscale, few techniques have the capability of probing the relationship between the two.…”

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confidence: 99%

Spatially Resolved Mapping of Electrical Conductivity across Individual Domain (Grain) Boundaries in Graphene

et al. 2013

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All large-scale graphene films contain extended topological defects dividing graphene into domains or grains. Here, we spatially map electronic transport near specific domain and grain boundaries in both epitaxial graphene grown on SiC and CVD graphene on Cu subsequently transferred to a SiO 2 substrate, with one-to-one correspondence to boundary structures.Boundaries coinciding with the substrate step on SiC exhibit a significant potential barrier for electron transport of epitaxial graphene due to the reduced charge transfer from the substrate near the step edge. Moreover, monolayer-bilayer boundaries exhibit a high resistance that can change depending on the height of substrate step coinciding at the boundary. In CVD graphene, the resistance of a grain boundary changes with the width of the disordered transition region between adjacent grains. A quantitative modeling of boundary resistance reveals the increased electron Published in ACS Nano 7, 7956 (2013).

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confidence: 99%

Spatially Resolved Mapping of Electrical Conductivity across Individual Domain (Grain) Boundaries in Graphene

et al. 2013

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“…10,32,33 This smaller shift in E f also yields a tiny modulation at negative V g as shown in Figure 3c. Our graphene based micro-ring modulator can potentially operate at tens of GHz.…”

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confidence: 73%

Efficient Modulation of 1.55 μm Radiation with Gated Graphene on a Silicon Microring Resonator

et al. 2014

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The gate-controllability of the Fermi-edge onset of interband absorption in graphene can be utilized to modulate near-infrared radiation in the telecommunication band. However, a high modulation efficiency has not been demonstrated to date, because of the small amount of light absorption in graphene. Here, we demonstrate a ~40% amplitude modulation of 1.55 µm radiation with gated single-layer graphene that is coupled with a silicon micro-ring resonator. Both the quality factor and resonance wavelength of the silicon micro-ring resonator were strongly modulated through gate tuning of the Fermi level in graphene.These results promise an efficient electro-optic modulator, ideal for applications in large-scale on-chip optical interconnects that are compatible with complementary metal-oxide-semiconductor technology.

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“…17 In previous work, 18 we developed a finite element (FE) model to investigate how the M4PP signature differs for measurements on 2D and quasi-1D materials; these signatures had already been observed experimentally. 15,16 We successfully validated the FE approach by comparing calculations for a single line defect to the analytical result. 19 The model was limited in its scope since only samples with insulating line defects were studied, which may be a reasonable representation of 2D materials in which current transport is dominated by transfer defects such as rips and tears.…”

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confidence: 99%

“…13 Micro four-point probe (M4PP) metrology has previously been used for non-destructive electrical characterization of graphene films. 14 M4PP metrology can be used to measure the sheet resistance (or sheet conductance), and in addition, the method allows for extraction and evaluation of geometry related parameters such as the resistance ratio 15,16 and the Hall effect signal caused by the Lorentz force. 17 In previous work, 18 we developed a finite element (FE) model to investigate how the M4PP signature differs for measurements on 2D and quasi-1D materials; these signatures had already been observed experimentally.…”

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Mesoscopic current transport in two-dimensional materials with grain boundaries: Four-point probe resistance and Hall effect

Lotz

Boll

Østerberg

et al. 2016

Journal of Applied Physics

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Anomalous Hall resistivity due to grain boundary in manganite thin films J. Appl. Phys. 93, 8107 (2003) We have studied the behavior of micro four-point probe (M4PP) measurements on two-dimensional (2D) sheets composed of grains of varying size and grain boundary resistivity by Monte Carlo based finite element (FE) modelling. The 2D sheet of the FE model was constructed using Voronoi tessellation to emulate a polycrystalline sheet, and a square sample was cut from the tessellated surface. Four-point resistances and Hall effect signals were calculated for a probe placed in the center of the square sample as a function of grain density n and grain boundary resistivity q GB . We find that the dual configuration sheet resistance as well as the resistance measured between opposing edges of the square sample have a simple unique dependency on the dimension-less parameter ffiffi ffi n p q GB G 0 , where G 0 is the sheet conductance of a grain. The value of the ratio R A =R B between resistances measured in A-and B-configurations depends on the dimensionality of the current transport (i.e., one-or two-dimensional). At low grain density or low grain boundary resistivity, two-dimensional transport is observed. In contrast, at moderate grain density and high grain resistivity, one-dimensional transport is seen. Ultimately, this affects how measurements on defective systems should be interpreted in order to extract relevant sample parameters. The Hall effect response in all M4PP configurations was only significant for moderate grain densities and fairly large grain boundary resistivity. Published by AIP Publishing. [http://dx

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Graphene Conductance Uniformity Mapping

Cited by 159 publications

References 66 publications

Spatially Resolved Mapping of Electrical Conductivity across Individual Domain (Grain) Boundaries in Graphene

Spatially Resolved Mapping of Electrical Conductivity across Individual Domain (Grain) Boundaries in Graphene

Efficient Modulation of 1.55 μm Radiation with Gated Graphene on a Silicon Microring Resonator

Mesoscopic current transport in two-dimensional materials with grain boundaries: Four-point probe resistance and Hall effect

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