Simulation of Heat Conduction in Suspended Graphene Flakes of Variable Shapes

Subrina, Samia; Kotchetkov, D.

doi:10.1166/jno.2008.303

Cited by 41 publications

(25 citation statements)

References 15 publications

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“…The thermal conductivity calculated with our model gives results consistent with the rigorous theory of heat conduction in graphene [7] and in excellent agreement with experiment [3][4]. Obtained results are important for the proposed graphene applications as lateral heat spreaders [4,6,[14][15] and interconnects [16] in future nanoelectronic and optoelectronic circuits.…”

supporting

confidence: 78%

Lattice thermal conductivity of graphene flakes: Comparison with bulk graphite

et al. 2009

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supporting

confidence: 78%

Lattice thermal conductivity of graphene flakes: Comparison with bulk graphite

et al. 2009

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“…It still remains unclear though how the thermal conductivity of graphene will be affected when it is embedded inside a device structure or used a multi-layer coating. The theoretical models described in this review can be incorporated into the simulation software for analysis of heat conduction in graphene layers and graphene devices (37) and help to answer the question of feasibility of the thermal management applications. …”

Section: Ecs Transactions 28 (5) 63-71 (2010)mentioning

confidence: 99%

Extraordinary Thermal Conductivity of Graphene: Possible Applications in Thermal Management

et al. 2010

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We review the results of our experimental and theoretical study of thermal conductivity of graphene. Using an original optical measurement technique we discovered that thermal conductivity of suspended graphene flakes is extremely high and can exceeds that of bulk graphite and carbon nanotubes. The high value of thermal conductivity of graphene and its dependence on the graphene flake size were explained within the framework of Klemens theory. Superior thermal properties of graphene benefit all proposed electronic applications of graphene and may lead to the new highheat flux thermal management solutions for advanced electronics.

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“…Graphene, a two dimensional sp 2 carbon allotrope arranged in a hexagonal pattern, exhibits unique mechanical and electronic properties, [1][2] exceptional conductivity, [3][4] large surface area, [5] and fast heterogeneous electron transfer. [6] Due to these outstanding characteristics, graphene platforms have been widely employed for electrochemistry.…”

Section: Introductionmentioning

confidence: 99%

Chemically Reduced Graphene Oxide for the Assessment of Food Quality: How the Electrochemical Platform Should Be Tailored to the Application

Chng

Ambrosi

Chua

et al. 2017

Chemistry A European J

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Graphene platforms have been drawing considerable attention in electrochemistry for the detection of various electroactive probes. Depending on the chemical composition and properties of the probe, graphene materials with diverse structural features may be required to achieve an optimal electrochemical performance. This work comprises a comparative study on three chemically modified graphenes, obtained from the same starting material and with different oxygen functionalities and structural defects (graphene oxide (GO), chemically reduced graphene oxide (CRGO), and thermally reduced graphene oxide (TRGO)) towards the electrochemical detection of quinine, an important flavoring agent present in tonic-based beverages. In general, the reduced graphenes, namely CRGO and TRGO, showed enhanced performance in terms of calibration sensitivity and selectivity, due to the improved heterogeneous electron-transfer rates on their surfaces. In particular, CRGO provided the best overall electrochemical performance, which can be attributed to its higher density of structural defects and reduced amount of oxygen functionalities. For this reason, CRGO was employed for the electrochemical detection of quinine in commercial tonic drink samples, showing high sensitivity and selectivity, and therefore representing a valid low-cost alternative to more complicated and time consuming traditional analytical methods.

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Simulation of Heat Conduction in Suspended Graphene Flakes of Variable Shapes

Cited by 41 publications

References 15 publications

Lattice thermal conductivity of graphene flakes: Comparison with bulk graphite

Lattice thermal conductivity of graphene flakes: Comparison with bulk graphite

Extraordinary Thermal Conductivity of Graphene: Possible Applications in Thermal Management

Chemically Reduced Graphene Oxide for the Assessment of Food Quality: How the Electrochemical Platform Should Be Tailored to the Application

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