Percolation and conduction in restricted geometries

Lajkó, Péter; Turban, L.

doi:10.1088/0305-4470/33/8/312

Cited by 10 publications

(9 citation statements)

References 25 publications

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“…Interestingly, the universal percolation exponents t and s for the 820 nm and 210 nm tubes have similar values. These values are close to those theoretically expected for a large conducting 2D network, − where s = t ≈ 1.3. Kholodenko and Freed argue for the exact 2D exponent value, 23/18 ≈ 1.28.…”

Section: Resultssupporting

confidence: 88%

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Influence of Nanotube Length on the Optical and Conductivity Properties of Thin Single-Wall Carbon Nanotube Networks

et al. 2008

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We study the optical and electrical properties of transparent conducting films made from length-sorted single-wall carbon nanotubes (SWCNT). Thin films of length-sorted SWCNTs, formed through filtration from a dispersing solvent onto a filter substrate ("buckypaper"), exhibit sharp changes in their optical properties and conductivity (sigma) with increasing SWCNT surface concentration. At a given surface concentration, tubes longer than 200 nm are found to form networks that are more transparent and conducting. We show that changes of sigma with SWCNT concentration can be quantitatively described by the generalized effective medium (GEM) theory. The scaling universal exponents describing the "percolation" transition from an insulating to a conducting state with increasing concentration are consistent with the two-dimensional (2D) percolation model. Shorter tubes and mixed length tubes form 3D networks. Furthermore, we demonstrate that the conductivity percolation threshold (x(c)) varies with the aspect ratio L as, x(c) approximately 1/L, a result that is also in accordance with the percolation theory. These findings provide a framework for engineering the optical and electrical properties of SWCNT networks for technological applications where flexibility, transparency, and conductivity are required.

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Section: Resultssupporting

confidence: 88%

“…Rather, they are found to be in accord with those predicted by GEM theory in 3D, s ≈ 0.8 and t ≈ 2.0. This indicates that an increasing fraction of SWCNT connections are being made in the third dimension in these short tube networks. ,, …”

Section: Resultsmentioning

confidence: 91%

Influence of Nanotube Length on the Optical and Conductivity Properties of Thin Single-Wall Carbon Nanotube Networks

et al. 2008

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“…The metallic data (Figure b) yield σ 0 = 3.3 × 10 –4 □ Ω –1 and h c = 12 ± 2 nm with a critical exponent of 0.92 ± 0.1, while the fit of the semiconducting data (Figure e) yields σ 0 = 7.7 x10 –5 □ Ω –1 and h c = 6 ± 2 nm with a critical exponent of 1.15 ± 0.1. Results from both film types are in agreement with accepted values of the critical exponent (α ≈ 1) for percolated 2D conducting networks. − Film thicknesses range from 9 to 72 nm, much less than the wavelength of light, and the transmittance as a function of sheet resistance, R s , is fit to the expression , T ( R S ) = true( 1 + 1 2 R normalS normalμ 0 normalε 0 normalσ normalo normalp normalσ normald normalc true) − 2 where ε 0 and μ 0 are the permittivity and permeability of free space, respectively, σ op is the optical conductivity, and σ dc is the direct current conductivity. The ratio σ op /σ dc quantifies the combined optical and electronic quality of the films.…”

Section: Resultssupporting

confidence: 78%

Electronic Durability of Flexible Transparent Films from Type-Specific Single-Wall Carbon Nanotubes

et al. 2011

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The coupling between mechanical flexibility and electronic performance is evaluated for thin films of metallic and semiconducting single-wall carbon nanotubes (SWCNTs) deposited on compliant supports. Percolated networks of type-purified SWCNTs are assembled as thin conducting coatings on elastic polymer substrates, and the sheet resistance is measured as a function of compression and cyclic strain through impedance spectroscopy. The wrinkling

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“…In the case of disordered systems, their physical behavior can usually be described by a power law with a percolation threshold and a critical exponent depending on the geometry [299,300,209,301] and on the conduction of the system [287,288,291,290,302]. One should also not exclude the local field changes in the composite due to interaction of inclusions.…”

Section: Percolation Theorymentioning

confidence: 99%

Dielectric mixtures: electrical properties and modeling

Tuncer

Serdyuk

Gubanski

2002

IEEE Trans. Dielect. Electr. Insul.

268

154

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A review of current state of understanding of dielectric mixture properties and approaches to use numerical calculations for their modeling are presented. It is shown that interfacial polarization can yield different non-Debye dielectric responses depending on the properties of the constituents, their concentrations and geometrical arrangements. Future challenges on the subject are also discussed.

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Percolation and conduction in restricted geometries

Cited by 10 publications

References 25 publications

Influence of Nanotube Length on the Optical and Conductivity Properties of Thin Single-Wall Carbon Nanotube Networks

Influence of Nanotube Length on the Optical and Conductivity Properties of Thin Single-Wall Carbon Nanotube Networks

Electronic Durability of Flexible Transparent Films from Type-Specific Single-Wall Carbon Nanotubes

Dielectric mixtures: electrical properties and modeling

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