TEM and Laser-Polarized <sup>129</sup>Xe NMR Characterization of Oxidatively Purified Carbon Nanotubes

Kneller, Julie M.; Soto, R.; Surber, S. E.; Colomer, Jean-François; Fonseca, A.; Nagy, J. B.; Tendeloo, and G. Van; Pietraβ, T.

doi:10.1021/ja994441y

Cited by 59 publications

(51 citation statements)

References 33 publications

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“…17 O in contrast to Δδ induce (−22 ppm). In comparison, a maximum shift of 2 ppm was predicted for 13 C in methanol B. This is also confirmed by the change of charge density (Δρ) in Figure 5b.…”

Section: Chemical Shifts Of Adsorbed Molecules Inside Cntssupporting

confidence: 73%

“…The vector map of ring current provides an intuitive and insight view to understand the effect of CNTs. This effect results in a similar shielding effect for all nuclei, for example, 13 C, 1 H, and 17 O in three different molecules. Electronic structure analysis for the host−guest and the guest−guest interactions indicates that the electronic effect makes the significant contribution to the chemical shifts of the polarizable atoms (such as 17 O).…”

Section: Resultsmentioning

confidence: 61%

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DFT Study on the NMR Chemical Shifts of Molecules Confined in Carbon Nanotubes

et al. 2013

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Large magnetic shielding has been experimentally observed on certain organic molecules, regardless of their intrinsically different chemical natures, when they are confined within the carbon nanotubes. We investigated the underlying physics of the shielding effect by employing a series of density functional theory calculations on various molecule-confined-in-CNT systems. Particularly, the effects of the intermolecular interaction and the ring current of the CNTs on the chemical shifts of the confined molecules were investigated in detail. The results reveal that the changes in chemical shift mainly originate from the magnetic shielding induced by the delocalized π electrons. Electronic structure analysis for nonbonded interactions of host−guest and guest−guest indicated that this intermolecular interaction effect on chemical shift is significant for the polarizable molecules. Thus, the NMR responses of the molecules confined in CNTs are different from those of the molecules in other confining environments. Our study thus suggested that the chemical shift can be used as a probe to distinguish the molecules inside and outside of the CNT channels, as well as the type of CNTs (such as metallic and semiconducting).

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Section: Chemical Shifts Of Adsorbed Molecules Inside Cntssupporting

confidence: 73%

Section: Resultsmentioning

confidence: 61%

DFT Study on the NMR Chemical Shifts of Molecules Confined in Carbon Nanotubes

et al. 2013

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“…The pretreatments shorten the CNTs and lead to the partial oxidation of the CNTs to produce functional oxygenated groups at the open ends and defects along the sidewall, in particular, which dramatically modify the electronic and structural properties of the nanotubes. [42][43][44][45][46][47] As a consequence, also very similar to other kinds of carbon-based materials mentioned above, the CNTs generally bear some functional oxygenated groups, of which some are electroactive. Li et al have observed a pair of redox waves at purified CNTs and ascribed them to the redox process of oxygenated groups produced at the CNTs, as shown below.…”

Section: Electrochemistry Of Cntsmentioning

confidence: 90%

Electrochemistry and Electroanalytical Applications of Carbon Nanotubes: A Review

et al. 2005

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Carbon nanotubes (CNTs) have been proved to be a novel type of nanostructure with unique structural, electronic and mechanical properties and have drawn extensive attention since their discovery. [1][2][3] Research over the past decade has revealed that the CNTs constitute a new form of carbon materials that are finding striking applications in many fields, such as energy conversion and storage, 4,5 electromechanical actuators, 6,7 chemical sensing 8 and so forth. Generally, the nanotubes can be divided into two categories: single-walled carbon nanotubes (SWNTs) and multi-walled carbon nanotubes (MWNTs). The former can be regarded as a graphene cylinder formed by rolling seamlessly a single graphene sheet along an (m,n) lattice vector in the sheet. The (m,n) indices is a central parameter governing the metallicity and chirality of the tubes. The latter is composed of coaxial multilayer graphene tubes with interlayer space of 0.34 nm. The diameter varies from 0.4 nm to 3 nm for the SWNTs and from 1.4 nm to 100 nm for the MWNTs (typical transmission electron microscopic images of the CNTs are shown in Fig. 1).Due to the unique physical and chemical properties and thus the striking applications in various research and industrial fields, the CNTs have drawn extensive interest over the past decade. To date, we have witnessed great successes in the synthesis of the CNTs and in understanding of their chemical and physical properties. Several excellent reviews concerning these issues have appeared in the literature. 9,10 Currently, increasing interests are being focused on the construction of the CNT-based functional nanodevices with novel properties for practical applications.On the other hand, the CNTs represent a new kind of carbonbased materials and are superior to other kinds of carbon materials commonly used in electrochemistry, such as glassy carbon (GC), graphite and diamond, mainly in the special structural features and unique electronic properties. As a result, besides their striking applications in other fields, study of the CNT electrochemistry thus far has revealed that these unique properties of the CNTs substantially make them useful for electrochemical investigations, e.g., electrocatalysis, direct electrochemistry of proteins and electroanalytical applications such as electrochemical sensors and biosensors. 11,12 The electroanalytical applications of the CNTs for construction of This review addresses recent developments in electrochemistry and electroanalytical chemistry of carbon nanotubes (CNTs). CNTs have been proved to possess unique electronic, chemical and structural features that make them very attractive for electrochemical studies and electrochemical applications. For example, the structural and electronic properties of the CNTs endow them with distinct electrocatalytic activities and capabilities for facilitating direct electrochemistry of proteins and enzymes from other kinds of carbon materials. These striking electrochemical properties of the CNTs pave the way to CNT-based bioelectrochemist...

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“…[60] Since that work, HP xenon has been used to study diffusion in confined spaces or porous media [61] , [62] , [63] ; image such systems as a function of gas flow [64] or 129 Xe chemical shift [65] ; or spectroscopically probe single-crystal surfaces [66] , liquid crystals, [67] or combustion processes. [68] However, the greatest body of materials-related work has concerned the effort to probe void spaces and surfaces in microporous or nanoporous materials with HP 129 Xe, thereby providing information about pore size, pore shape, and gas dynamics in: nanochanneled organic, organometallic, and peptide-based molecular materials [69] (including in macroscopically oriented single crystals [70] ); multi-walled carbon nanotubes [71] ; gas hydrate clathrates [72] ; porous polymeric materials and aerogels [73] ; metalorganic frameworks [74] ; calixarene-based materials and nanoparticles [75] ; organo-clays [76] ; mesoporous silicas [77] ; and zeolites and related materials [78] -efforts that have been aided by computational studies of xenon in confined spaces (e.g., Refs. [79] ).…”

Section: 1002/chem201603884 Chemistry -A European Journalmentioning

confidence: 99%

NMR Hyperpolarization Techniques of Gases

Barskiy

Coffey

Nikolaou

et al. 2016

Chemistry A European J

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Nuclear spin polarization can be significantly increased through the process of hyperpolarization, leading to an increase in the sensitivity of nuclear magnetic resonance (NMR) experiments by 4-8 orders of magnitude. Hyperpolarized gases, unlike liquids and solids, can be more readily separated and purified from the compounds used to mediate the hyperpolarization processes. These pure hyperpolarized gases enabled many novel MRI applications including the visualization of void spaces, imaging of lung function, and remote detection. Additionally, hyperpolarized gases can be dissolved in liquids and can be used as sensitive molecular probes and reporters. This mini-review covers the fundamentals of the preparation of hyperpolarized gases and focuses on selected applications of interest to biomedicine and materials science.

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TEM and Laser-Polarized ¹²⁹Xe NMR Characterization of Oxidatively Purified Carbon Nanotubes

Cited by 59 publications

References 33 publications

DFT Study on the NMR Chemical Shifts of Molecules Confined in Carbon Nanotubes

DFT Study on the NMR Chemical Shifts of Molecules Confined in Carbon Nanotubes

Electrochemistry and Electroanalytical Applications of Carbon Nanotubes: A Review

NMR Hyperpolarization Techniques of Gases

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TEM and Laser-Polarized 129Xe NMR Characterization of Oxidatively Purified Carbon Nanotubes

Cited by 59 publications

References 33 publications

DFT Study on the NMR Chemical Shifts of Molecules Confined in Carbon Nanotubes

DFT Study on the NMR Chemical Shifts of Molecules Confined in Carbon Nanotubes

Electrochemistry and Electroanalytical Applications of Carbon Nanotubes: A Review

NMR Hyperpolarization Techniques of Gases

Contact Info

Product

Resources

About

TEM and Laser-Polarized ¹²⁹Xe NMR Characterization of Oxidatively Purified Carbon Nanotubes