Role of extrinsic atoms on the morphology and field emission properties of carbon nanotubes

Chan, L.; Hong, Kunquan; Xiao, Dongyang; Hsieh, Wei-Jen; Lai, Shih-Hsiang; Shih, Han C.; Lin, Ting-Yu; Shieu, Fuh‐Sheng; Chen, K. J.; Cheng, Huang–Chung

doi:10.1063/1.1579136

Cited by 67 publications

(25 citation statements)

References 26 publications

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“…Table 1 lists the field emission properties of the a-C:N and a-C:N:B films. A higher field is required to emit electrons from a-C:N:B film for the following reasons: (1) Degree of graphitization: The field emission characteristics can be [31]. Both generation of holes and recombination effect can decrease emission current, thereby leading to a higher threshold field (5.2 V/lm).…”

Section: Field Emission Measurementmentioning

confidence: 99%

Cathodoluminescence and electron field emission of boron-doped a-C:N films

Hsieh

Lai

Chan

et al. 2005

Carbon

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Section: Field Emission Measurementmentioning

confidence: 99%

Cathodoluminescence and electron field emission of boron-doped a-C:N films

Hsieh

Lai

Chan

et al. 2005

Carbon

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“…The proportion of nitrogen in CNTs is approximately 8%, as revealed by EDX. Addition of N 2 to the process gas is believed to promote the formation of a bamboo-like structure having a surface with a small radius of curvature [101][102][103]. Moreover, the incorporation of nitrogen atoms into graphene sheets with a bamboo-like structure favors the formation of pentagons and heptagons, and increases the reactivity of the neighboring carbon atoms, yielding the decorated nanotubes.…”

Section: Direct Growth Of Cnts On Carbon Cloth (Cnt-cc)mentioning

confidence: 99%

Carbon Nanotube‐Supported Catalysts for the Direct Methanol Fuel Cell

Wang

Chen

2009

Electrocatalysis of Direct Methanol Fuel Cells

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Fuel cells generate power by converting chemical energy to electricity via electrochemical reactions, which involve eco-friendly reactants and products, in comparison to conventional power generators based on the internal combustion engine. Accordingly, the fuel cell is an attractive and promising power generator with a wide range of applications in sensors, portable devices, automotives, and stationary power systems. The direct methanol fuel cell (DMFC) resembles the proton exchange membrane fuel cell (PEMFC) in its power-generating unit, and the membrane electrode assembly (MEA) with a proton exchange-membrane that is sandwiched between two electrodes. However, instead of hydrogen gas, which is used as fuel in a PEMFC, the DMFC uses a methanol solution as the fuel feeding the anode. The methanol is oxidized to CO 2 , via an electrochemical process, at the anode and the air is reduced at the cathode to generate the electricity. With methanol solution as fuel, the DMFC system can be operated without a humidification unit, which is essential for the pure hydrogen PEM systems. The fact that methanol solution can be easily stored and refilled and hence can provide a relatively high energy density of 6.08 Whg À1 (neat methanol) makes the DMFC a potential solution as a mobile energy source. Therefore, the DMFC system, rather than a secondary battery (such as Li-ion battery), is regarded as a next-generation power source in a portable system.Despite all the advantages of DMFC, the sluggish methanol oxidation rate and the methanol crossover detrimentally affect its performance. A key technology for the development of DMFC is the development of a highly efficient MEA, in which the methanol can be easily and rapidly oxidized by the catalysts before it arrives at the membrane. As evident from literature, the uniform deposition of carbon-supported nanoscale catalysts, Pt-Ru with an atomic ratio of 1 : 1, coated on the gas diffusion layer (i.e., carbon cloth and carbon paper) has been widely adopted to provide the catalyst layer of the anode in the DMFC [1][2][3]. Besides the catalysts, the carbon support also markedly interferes with the MEA performance due to its role in Electrocatalysis of Direct Methanol Fuel Cells. Edited j315 stabilizing the catalysts, providing diffusion channels and conduction of the output electrons. Traditionally, carbon blacks (CBs), possessing moderate conductivity and large surface area, are widely adopted as the carbon supports. For example, Vulcan XC-72 with an electrical conductivity of 0.25 S cm À1 and a BETsurface area of 237 m 2 g À1 , is extensively used as carbon supports [4]. Although the CBs is normally selected as the support for the fuel cell, a new carbon support with higher conductivity and larger surface area is desired. Recently, carbon nanotubes (CNTs) with a large surface area, high electrical conductivity, and unique shape [5,6] have emerged as potential carbon supports in fuel cell applications. Numerous works have attempted to disperse platinum (Pt/CNT) or platinum-ruthenium...

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“…The change in the electronic structures can modify the field emission properties significantly. Thus, the control of the electronic structures of CNTs is of great technological importance, and the adsorption [6][7][8] and doping [9,10] of extrinsic atoms or molecules are the best way to accomplish this goal. With the development of the synthesis techniques, various kinds of doped CNTs have been fabricated [11].…”

Section: Introductionmentioning

confidence: 99%

“…N-and B-doped CNTs have been successfully synthesized using different techniques [13,14]. The existing experimental investigations indicate that N-doped CNTs show an enhanced electron field emission and special emission properties [9,[15][16][17] when compared with pristine CNTs. On the other hand, the experimental results, reported by Charlier et al [18], demonstrate that B-doped CNTs exhibit a stable electron field emission at lower turn-on voltage.…”

Section: Introductionmentioning

confidence: 99%

“…On the other hand, the experimental results, reported by Charlier et al [18], demonstrate that B-doped CNTs exhibit a stable electron field emission at lower turn-on voltage. However, Chan et al [9] have experimentally found that the incorporation of boron into CNT eventually impedes the electron field emission properties. Due to the existing contradicted experimental results, it is therefore of great interest to theoretically investigate how the doping of boron atom can affect the field emission properties of CNTs.…”

Section: Introductionmentioning

confidence: 99%

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