Improvement of emission characteristics uniformity of carbon nanotube field emission display by surface treatment

Shiroishi, Tetsuya; Hosono, A.; Sono, Atsuhiro; Nishimura, Kohei; Suzuki, Yousuke; Nakata, Shuhei; Okuda, Satoshi

doi:10.1116/1.2172955

Cited by 10 publications

(7 citation statements)

References 9 publications

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“…Subsequently, the sample was exposed to single 25 ns pulses from a 248 nm UV excimer laser (Lambda Physik LPX210i) over a range of energies. The area of the laser spot was 0.18 cm A numerical summary of the FE characteristics is presented in Table 1 These results show strikingly similar changes in the FE characteristics to those observed by Hosono et al 23,24 In their work, a CNT-resin paste, screen printed onto glass substrates was laser treated. Here, pure o-MWNT inks on paper substrates are irradiated, suggesting that this technique can routinely be applied to CNT inks to improve their FE characteristics.…”

Section: 14supporting

confidence: 70%

Improved field emission via laser processing of carbon nanotubes on paper substrates

Lyth

Henley

Silva

2009

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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Field emission (FE) is the emission of electrons from a solid by the application of a high electric field via quantum mechanical tunneling of electrons through a potential barrier. Carbon nanotubes (CNTs) have excellent FE properties, 1,2,3,4 The morphology of a surface plays a crucial role in determining its FE properties. 15,16 The local field at the emission site governs FE, so micron and nanoscale protrusions can enhance FE due to increased electric field concentration at their surfaces. This enhancement is described by the field enhancement factor (β); the factor by which the local electric field exceeds the macroscopic applied electric field.Therefore, by altering the morphology of an emitter, β and the FE properties can be modified.In this article the deposition of multiwall carbon nanotube ink (MWNT) onto paper substrates via a straightforward dip-coating technique is investigated as a means to increase β by taking advantage of the inherent roughness of the substrate. Paper substrates were chosen as low cost, flexible, readily available materials, and as established substrates for printing technologies. It has already been determined that MWNTs deposited onto paper substrates can have excellent FE properties, which can be tailored according to the morphology of the specific paper substrate utillzed. 17 Here, the effects of a postdeposition excimer laser treatment on the morphology and, therefore, FE characteristics of such samples are investigated.MWNTs with a nominal diameter of 10 nm were purchased from Nanocyl and ultrasonically dispersed in a 3:1 concentrated sulfuric and nitric acid mixture for 10 min. The mixture was refluxed at elevated temperature for 40 min before diluting with de-ionized water. This process results in the formation of carboxylic acid groups attached to the MWNT ends and sidewalls, which interact with water molecules via hydrogen bonding. Large particles and agglomerates were removed from the solution by centrifuging. The centrifuged liquid was carefully decanted, filtered, and washed with de-ionized

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Section: 14supporting

confidence: 70%

Improved field emission via laser processing of carbon nanotubes on paper substrates

Lyth

Henley

Silva

2009

Journal of Vacuum Science &Amp; Technology B: Microelectronics and Nanometer Structures Processing, Measurement, and Phenomena

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“…To improve adhesion and emission uniformity of cathode film, CNT paste was synthesized using different inorganic and organic vehicles [7,8]. In addition, laser treatment [9][10][11], plasma treatment [12], mechanical rubbing [13][14][15] and adhesive tapping [16] have been applied to increase effective CNT emitters. Moreover, processing temperature and time [17,18] as effective parameter are also studied to activate more emission sites.…”

Section: Introductionmentioning

confidence: 99%

Enhanced field emission characteristics of zinc oxide mixed carbon nano-tubes films

Pan

Chen

Gao

2008

Applied Surface Science

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“…Li research group improved contact performance by inserting a transition layer between carbon nanotubes and substrate [6][7][8][9]. Chen group [10,11] discovered that the electron tunneling would be affected by the contact surface barrier between carbon nanotubes and substrate. Different Fower-Nordheim curves have been attributed for different kinds of Ohmic and Schottky contacts in their research.…”

Section: Introductionmentioning

confidence: 99%

“…Different Fower-Nordheim curves have been attributed for different kinds of Ohmic and Schottky contacts in their research. Shiroishi [11] research group decreased the turn-on voltage from 2.1 to 1.4 V/μm and improved the field emission characteristics by laser posttreatment on the carbon nanotubes. Yu [13] group selectively etched the carbon nanotubes film prepared through screenprinting, so as to remove the inorganic binder within the CNT cathode film and to enhance emission performance effectively.…”

Section: Introductionmentioning

confidence: 99%

Field Emission Properties of the Dendritic Carbon Nanotubes Film Embedded with ZnO Quantum Dots

Zuo

Liu

et al. 2011

Journal of Nanomaterials

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Response on the effects of individual differences of common carbon nanotubes on the field emission current stability and the luminescence uniformity of cathode film, a new type of cathode film made of dendritic carbon nanotubes embedded with Zinc oxide quantum dots is proposed. The film of dendritic carbon nanotubes was synthesized through high-temperature pyrolysis of iron phthalocyanine on a silicon substrate coated with zinc oxide nanoparticles. The dendritic structure looks like many small branches protrude from the main branches in SEM and TEM images, and both the branch and the trunk are embedded with Zinc oxide quantum dots. The turn-on field of the dendritic structure film is∼1.3 V/μm at a current of 2 μA, which is much lower than that of the common carbon nanotube film, and the emission current and the luminescence uniformity are better than that of the common one. The whole film emission uniformity has been improved because the multi-emission sites out from the dendritic structure carbon nanotubes cover up the failure and defects of the single emission site.

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Improvement of emission characteristics uniformity of carbon nanotube field emission display by surface treatment

Cited by 10 publications

References 9 publications

Improved field emission via laser processing of carbon nanotubes on paper substrates

Improved field emission via laser processing of carbon nanotubes on paper substrates

Enhanced field emission characteristics of zinc oxide mixed carbon nano-tubes films

Field Emission Properties of the Dendritic Carbon Nanotubes Film Embedded with ZnO Quantum Dots

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