Physisorption Kinetics in Carbon Nanotube Bundles

and, J. Tanori; Calbi, M. Mercedes

doi:10.1021/jp065428k

Cited by 38 publications

(105 citation statements)

References 39 publications

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“…The theoretical studies have also found that a completely different mechanism for reaching equilibrium exists for nanotubes that have open ends. 13 In previous publications, in which we studied gas adsorption kinetics on closed-and openended nanotubes, we determined experimentally that these predictions were correct. 4,5 Here we explore the dependence of the equilibration time on the length of the adsorbed molecule, and, for each adsorbate, we also explore the dependence of the equilibration time on fractional coverage.…”

Section: Introductionmentioning

confidence: 80%

Non-Monotonic Kinetics of Alkane Adsorption on Single-Walled Carbon Nanotubes

Rawat

Migone

2011

J. Phys. Chem. C

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We report kinetics measurements for the adsorption of methane, ethane, propane, butane, and pentane on close-ended single-walled carbon nanotube bundles. The measurements were conducted by monitoring the adsorption equilibration times. For methane and ethane, equilibration times were found to decrease as the fractional coverage on the surface of the nanotube bundles increased, approaching monolayer completion. However, for propane, butane, and pentane, the opposite trend was observed: for these longer alkanes, there was an increase in the equilibration time with increasing fractional coverage. We propose a plausible explanation for our experimental findings, and we suggest that different mechanisms for attaining equilibrium may be in place for short and long alkane chains.

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Section: Introductionmentioning

confidence: 80%

Non-Monotonic Kinetics of Alkane Adsorption on Single-Walled Carbon Nanotubes

Rawat

Migone

2011

J. Phys. Chem. C

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“…It is interesting to note that the adsorption reaches equilibrium much faster on external sites (grooves and outer surfaces) than on the internal sites (interstitial channels and inside the tube) under the same pressure and temperature conditions. The external sites are directly exposed to the adsorbing material; the adsorption process on internal sites has to be initiated on the ends of the pore, followed by diffusion to the sites at the interior [49,50]. Second, the fraction of opened and unblocked nanotubes can greatly influence the overall adsorption capacity.…”

Section: Adsorption Properties Of Cntsmentioning

confidence: 99%

Carbon nanotubes as adsorbents in environmental pollution management: A review

Ren

Chen

Nagatsu

et al. 2011

Chemical Engineering Journal

984

357

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“…It is interesting to note that recent theoretical calculations by Calbi et al, have predicted a two orders of magnitude longer adsorption time of gases to IC sites compared to OG sites. 50 Their prediction was confirmed by experimental adsorption studies of Ar on open-ended SWNT bundles by Migone et al, 51 To do a quantitative analysis of the data, we tried applying a random-walk diffusion model 52 to our data. According to this model, an initial packet of particles would diffuse out over time (t) through collisions with the environment similarly to a random-walk process, and this packet's mean-square displacement would be described as (in one dimension) where x 2 is the mean-square displacement and D is the diffusion coefficient.…”

Section: A 4 He Binding Energies On Single-wall Carbon Nanotube Bundmentioning

confidence: 55%

“…14 Also, Calbi et al, have predicted much slower adsorption of gases to IC sites due to diffusive adsorption process. 50 So we interpret the y intercept value as the number of atoms adsorbed onto OG site. 55 Using some further assumptions [the mean-square displacement divided by the adsorbate distance is the number of adsorbates in the diffusion channel (IC sites)], we obtained the diffusion coefficient from the slope as well.…”

Section: A 4 He Binding Energies On Single-wall Carbon Nanotube Bundmentioning

confidence: 99%

Gas adsorption on single-wall carbon nanotube bundles and charcoal samples

2011

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We have studied the adsorption properties of 4 He on single-wall carbon nanotube (SWNT) bundles and activated carbon (charcoal) samples using a temperature-programmed desorption (TPD) technique. The 4 He binding energy, the dose temperature dependence of adsorption, and the competitive adsorption of binary mixture gases among 4 He, 3 He, H 2 , and Xe were measured. The energy on SWNTs was as high as 910 K at ∼1 × 10 17 atom/mg coverage, decreased as the coverage increased, and agrees with the previously reported energy values where the coverages overlap. On charcoal the 4 He binding energy was constant at 403 ± 11 K. 4 He adsorption showed an activated adsorption behavior when 4 He was dosed below ∼30 K with activation energy ∼20 K to some sites of the SWNT bundles. We argue that these sites are interstitial channel (IC) sites, and the activated adsorption was the reason why some of the previously reported gas adsorption studies where 4 He was dosed at low temperature could not detect IC adsorption. On charcoal 4 He did not show activated adsorption behavior when dosed at ∼15 K. Mixture gas adsorption measurements on SWNT samples showed that the relative binding strengths were 3 He < 4 He < H 2 < Xe. Results showing 3 He < 4 He coincide with the predictions of quantum sieving on SWNT bundles. When 4 He was dosed at 275 K and H 2 was dosed at 19 K, 4 He adsorption was stable against H 2 , which indicates limited access of H 2 at low temperature to some of the sites where 4 He preadsorbed. Again we argue that the likely candidates for such sites are IC sites on SWNT bundles.

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Physisorption Kinetics in Carbon Nanotube Bundles

Cited by 38 publications

References 39 publications

Non-Monotonic Kinetics of Alkane Adsorption on Single-Walled Carbon Nanotubes

Non-Monotonic Kinetics of Alkane Adsorption on Single-Walled Carbon Nanotubes

Carbon nanotubes as adsorbents in environmental pollution management: A review

Gas adsorption on single-wall carbon nanotube bundles and charcoal samples

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