High emission current density microwave-plasma-grown carbon nanotube arrays by postdepositional radio-frequency oxygen plasma treatment

Chen, Z.; Engelsen, Daniel den; Bachmann, Peter K.; Elsbergen, V. van; Koehler, I.; Merikhi, J.; Wiechert, Detlef

doi:10.1063/1.2140893

Cited by 51 publications

(32 citation statements)

References 21 publications

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“…Indeed, this finding is consistent with the results reported by other researchers showing that oxygen improves the electronic emission properties of CNTs. 12,[28][29][30][31][32] The band associated with the O1s core level electrons is located at a relatively low binding energy (530.3 eV), that was recently attributed to the C ¼ O bond of quinoid groups. 33 In particular, within this group there is a functional group, called benzoquinone, which contains two oxygen atoms doubly bonded to carbon in terminal parts of the structure.…”

Section: Electronic Propertiesmentioning

confidence: 99%

Effect of O2+, H2++ O2+, and N2++ O2+ ion-beam irradiation on the field emission properties of carbon nanotubes

Acuña

Escobar

Goyanes³

et al. 2011

Journal of Applied Physics

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The effect of O2+, H2++ O2+, and N2++ O2+ ion-beam irradiation of carbon nanotubes (CNTs) films on the chemical and electronic properties of the material is reported. The CNTs were grown by the chemical vapor deposition technique (CVD) on silicon TiN coated substrates previously decorated with Ni particles. The Ni decoration and TiN coating were successively deposited by ion-beam assisted deposition (IBAD) and afterwards the nanotubes were grown. The whole deposition procedure was performed in situ as well as the study of the effect of ion-beam irradiation on the CNTs by x-ray photoelectron spectroscopy (XPS). Raman scattering, field-effect emission gun scanning electron microscopy (FEG-SEM), and field emission (FE) measurements were performed ex situ. The experimental data show that: (a) the presence of either H2+ or N2+ ions in the irradiation beam determines the oxygen concentration remaining in the samples as well as the studied structural characteristics; (b) due to the experimental conditions used in the study, no morphological changes have been observed after irradiation of the CNTs; (c) the FE experiments indicate that the electron emission from the CNTs follows the Fowler-Nordheim model, and it is dependent on the oxygen concentration remaining in the samples; and (d) in association with FE results, the XPS data suggest that the formation of terminal quinone groups decreases the CNTs work function of the material.

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Section: Electronic Propertiesmentioning

confidence: 99%

Effect of O2+, H2++ O2+, and N2++ O2+ ion-beam irradiation on the field emission properties of carbon nanotubes

Acuña

Escobar

Goyanes³

et al. 2011

Journal of Applied Physics

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“…CNT arrays (CNTAs) cold cathodes show low turn-on/threshold fields and high current emission density, and they are fabricated by thermal chemical vapor deposition (TCVD), plasma enhanced CVD (PECVD), and microwave PECVD (MWPECVD) techniques [11][12][13]. Screen-printing is another method to fabricate CNT emitters, by which the raw materials CNTs can be obtained independently.…”

Section: Introductionmentioning

confidence: 99%

Large field emission current and density from robust carbon nanotube cathodes for continuous and pulsed electron sources

et al. 2017

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“…15͒ has been used to alter the FE properties of CNT arrays by removing surface amorphous carbon impurities, 16,17 introducing defects, 15 and by modifying the work function of the surface of the CNTs. 12 Previous work has shown that O 2 impurities etch the base of the CNTs during FE characterization due to large contact resistances between the substrate and CNTs, resulting in an increase in threshold field. 18 Our previous work has revealed that polystyrene ͑PS͒-multiwall carbon nanotube ͑MWNT͒ composite films exhibit excellent FE properties ͑low threshold fields: 1.6 V / m͒ from the fracture surface at relatively low CNT concentrations ͑ca.…”

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confidence: 99%

Polymer supported carbon nanotube arrays for field emission and sensor devices

Watts

Lyth

Mendoza

et al. 2006

Applied Physics Letters

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The authors report a simple method for providing a polymer support structure for carbon nanotube ͑CNT͒ arrays for device applications. This method has a twofold effect: firstly it secures the nanotubes to the substrate and secondly it significantly decreases the threshold field for field emission from 26.2 to 9.7 V / m. This method ensures that the main body and tips of the CNTs are polymer-free and therefore can also be applied to CNT sensor array device fabrication. © 2006 American Institute of Physics. ͓DOI: 10.1063/1.2345615͔ Aligned carbon nanotube ͑CNT͒ arrays 1,2 are attracting increased interest for sensing applications and are currently studied as platforms for a variety of sensor devices 3-5 and field emission ͑FE͒ sources in flat screen displays.6,7 An underlying drawback for CNT arrays being used as sensing platforms is the fact that the nanotubes are weakly bound to the silicon substrate and are susceptible to facile detachment ͓Fig. 1͑a͒: effect from scratching͔, which reduces performance and lifetime, when incorporated in sensor and display technologies. Recently, there has been much investigation into the possible toxicological effects of carbon nanotubes with biological systems. 8,9 In the case of CNT electrophysiological sensors, 10 nanotube detachment from the substrate becomes an important issue.There are several additional issues to be tackled if CNTs are to become viable FE materials, such as improvement of turn on fields, mechanical stability, and the robustness of the substrates. Degradation of CNT arrays during FE occurs mainly due to mechanical failure at the tube-substrate contact and resistive heating.11 Plasma post-treatment with O 2 , 12 CF 4 , 13 Ar, 14 and H 2 ͑Ref. 15͒ has been used to alter the FE properties of CNT arrays by removing surface amorphous carbon impurities, 16,17 introducing defects, 15 and by modifying the work function of the surface of the CNTs.12 Previous work has shown that O 2 impurities etch the base of the CNTs during FE characterization due to large contact resistances between the substrate and CNTs, resulting in an increase in threshold field. 18Our previous work has revealed that polystyrene ͑PS͒-multiwall carbon nanotube ͑MWNT͒ composite films exhibit excellent FE properties ͑low threshold fields: 1.6 V / m͒ from the fracture surface at relatively low CNT concentrations ͑ca. 12 wt. %͒. 19,20 Further investigation of the fracture surface by scanning electron microscopy ͑SEM͒ shows that after the MWNTs have been pulled out of the PS matrix, there remains polymer attached to the nanotube surface, indicating good adhesion between the tubes and polymer ͓Fig. 1͑b͔͒.We have developed a facile method for the fabrication of a thin PS support, which holds the tubes securely to the substrate surface while ensuring that the nanotubes are free of polymer and available for FE and chemical/biological functionalization. We demonstrate that the FE properties are noticeably enhanced after the polymer layer has been fabricated due to the oxygen plasma treatment step. Thres...

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High emission current density microwave-plasma-grown carbon nanotube arrays by postdepositional radio-frequency oxygen plasma treatment

Cited by 51 publications

References 21 publications

Effect of O2+, H2++ O2+, and N2++ O2+ ion-beam irradiation on the field emission properties of carbon nanotubes

Effect of O2+, H2++ O2+, and N2++ O2+ ion-beam irradiation on the field emission properties of carbon nanotubes

Large field emission current and density from robust carbon nanotube cathodes for continuous and pulsed electron sources

Polymer supported carbon nanotube arrays for field emission and sensor devices

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