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Fabrication, Purification and Characterization of Carbon Nanotubes: Arc-Discharge in Liquid Media (ADLM)

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Mohsen Jahanshahi and Asieh Dehghani Kiadehi

Submitted: 15 June 2012 Published: 09 May 2013

DOI: 10.5772/51116

Syntheses and Applications of Carbon Nanotubes and Their Composites IntechOpen
Syntheses and Applications of Carbon Nanotubes and Their Composit... Edited by Satoru Suzuki

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Syntheses and Applications of Carbon Nanotubes and Their Composites

Edited by Satoru Suzuki

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1. Introduction

Carbon nanotubes (CNTs) were first discovered by Iijima in 1991 [1]. CNTs have sparked great interest in many scientific fields such as physics, chemistry, and electrical engineering [2, 3]. CNTs are composed of graphene sheets rolled into closed concentric cylinders with diameter of the order of nanometers and length of micrometers. CNTs are in two kinds, based on number of walls, the single-walled and multi-walled.

The diameter of single walled carbon nanotubes (SWNTs) ranges from 0.4 nm to 3nm and the length can be more than 10 mm that makes SWNTs good experimental templates to study one-dimensional mesoscopic physics system [3]. These unique properties have been the engines of the rapid development in scientific studies in carbon based mesoscopic physics and numerous applications such as high performance field effect transistors [4-9], single-electron transistors [10, 11], atomic force microscope tips [12], field emitters [13, 14], chemical/biochemical sensors [15-18], hydrogen storage [19].

There are three important methods to produce high quality CNT namely laser [20], arc discharge [21, 22], and Chemical Vapor Deposition (CVD) [23, 24]. Recently, arc discharge in liquid media has been developed to synthesize several types of nano-carbon structures such as: carbon onions, carbon nanohorns and carbon nanotubes. This is a low cost technique as it does not require expensive apparatus [25,26].

However, several techniques such as oxidation, nitric acid reflux, HCl reflux, organic functionalization, filtration, mechanical purification and chromatographic purification have been developed that separate the amorphous carbons and catalyst nanoparticles from the CNTs while a significant amount of CNTs are also destroyed during these purification processes [27].

In this review paper, synthesis, purification and structural characterization of CNTs based on arc discharge in liquid media are reviewed and discussed. In addition, several parameters such as: voltage difference between electrodes, current, type and ratio of catalysts, electrical conductivity, concentration, type and temperature of plasma solution, as well as thermal conductivity on carbon nanotubes production are investigated.

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2. Synthesis of CNTs

2.1. Laser vaporization

The laser vaporization method was developed for CNT production by Smalley's group [28, 29]. The laser is suitable for materials with high boiling temperature elements such as carbon because of its high energy density. The quantities of CNTs, in this method are large. Smalley's group further developed the laser method also known as the laser-furnace method [28]. Fullerenes with a soccer ball structure are produced only at high furnace temperatures, underlining the importance of annealing for nanostructures [28]. These discoveries were applied to produce CNTs [29] in 1996, especially SWNTs. A beam of high power laser impinges on a graphite target sitting in a furnace at high temperature as Figure1 shows.

Figure 1.

Schematic drawing of a laser obtain.

The target is vaporized in high-temperature buffer gas like Ar and formed CNTs. The produced CNTs are conveyed by the buffer gas to the trap, where they are collected. Then CNTs can be found in the soot at cold end.

This method has several advantages, such as high-quality CNTs production, diameter control, investigation of growth dynamics, and the production of new materials. High-quality CNTs with minimal defects and contaminants, such as amorphous carbon and catalytic metals, have been produced using the laser-furnace method together with purification processes [30-32] but the laser has sufficiently high energy density to vaporize target at the molecular level. The graphite vapor is converted into amorphous carbon as the starting material of CNTs [33-35]. However, the laser technique is not economically advantageous, since the process involves high purity graphite rods, high power lasers and low yield of CNTs.

2.2. Chemical vapor deposition (CVD)

The chemical vapor deposition (CVD) is another method for producing CNTs in which a hydrocarbon vapor is thermally decomposed in the presence of a metal catalyst. In this method, carbon source is placed in gas phase in reaction chamber as shown in Figure 2. The synthesis is achieved by breaking the gaseous carbon molecules, such as methane, carbon monoxide and acetylene, into reactive atomic carbon in a high temperature furnace and sometime helped by plasma to enhance the generation of atomic carbon [36].

This carbon will get diffused towards substrate, which is coated with catalyst and nanotubes grow over this metal catalyst. Temperature used for synthesis of nanotube is 650 – 900 0C range and the typical yield is 30% [36].

Figure 2.

Schematic diagram of a CVD setup.

In fact, CVD has been used for producing [37-39] carbon filaments and fibers since 1959. Figure 2 shows a schematic diagram of the setup used for CNT growth by CVD in its simplest form. CNTs grow over the catalyst and are collected upon cooling the system to room temperature. The catalyst material may be different, solid, liquid, or gas and can be placed inside the furnace or fed in from outside [40, 41].

2.3. Arc Discharge

A schematic diagram of the arc discharge apparatus for producing CNTs is shown in Figure 3. In this method, two graphite electrodes are installed vertically, and the distance between the two rod tips is usually in the range of 1–2 mm. The anode and cathode are made of pure graphite (those are, with a purity of 99.999%).

The anode is drilled, and the hole is filled with catalyst metal powder then the chamber is connected to a vacuum line with a diffusion pump and to a gas supply [43]. Like the anode in a DC electric arc discharge reactor, CNT is synthesized of graphite rod. After the evacuation of the chamber by a diffusion pump, rarefied ambient gas is introduced [43].

Figure 3.

Schematic diagram of apparatus for preparing CNTs.

When a dc arc discharge is applied between the two graphite rods, the anode is consumed, and fullerene is formed in the chamber soot [43]. The mass production of multi wall carbon nanotubes (MWCNTs) by this dc arc discharge evaporation was first achieved by Ebbesen and Ajayan [44].

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3. Arc-Discharge in Liquid Media (ADLM)

The traditional arc-plasma growth method for CNTs necessitates complex gas-handling equipment, a sealed reaction chamber, a liquid-cooled system and time consuming purge cycles. The act of extraction of nanotube’s product is so complicated [45]. To be compared, the growth of arc plasma in water requires simple operation and equipment which had made the process of CNTs production noticeable [47].

Ishigami et al. [48] developed a simple arc method in liquid nitrogen for the first time that allow for the continuous synthesis of high-quality CNTs. The materials obtained are mainly MWCNTs, amorphous carbon, graphitic particles and carbonaceous material [48, 49]. Subsequently, an aqueous arc-discharge (arc-water) method was developed. Lange et al. [50] generated onions, nanotubes and encapsulates by arc discharge in water. Figure 4 is shown produced CNTs in LiCl 0.25 N media [51].

Figure 4.

Carbon nanotubes produced in LiCl 0.25 N [51].

The arc discharge in liquid is initiated between two high purity graphite electrodes. Figure 5 is shown schematic device of arc discharge in liquid. Both electrodes are submerged in the liquid in a beaker. At first, the electrodes touch each other and are connected with a direct current (DC) power supply.

Figure 5.

Schematic device of arc discharge in liquid.

The cathode is usually 20 mm in diameter, while the anode is 6 mm in diameter. Then the arc discharge is initiated by slowly detaching the moveable anode from the cathode. The arc gap is kept at the proper value (about 1 mm) that the continuous arc discharge could be obtained [52].

Recently carbon nanotubes (CNTs) were fabricated successfully with arc discharge in solution by a novel full automatic set up [51].

The arc discharge and consequently consumption of anode result to increase the distance between the two electrodes and degrees the voltage between them as well. In order to remain constant voltage and gap between the two electrodes, the program automatically will compare the initial voltage with the voltage of two electrodes with an accuracy of 0.1 V. Based on the calculated difference the program calculates the proportional coefficient for the proportional controller. Figure 6 is schematic of the apparatus used for automatic arc discharge in solution [51].

During the arc discharge, the gap between the two electrodes is maintained at approximately 1 mm, while the synthesis time is 60 s [51].

Figure 6.

Schematic of the apparatus used for automatic arc discharge in solution [51].

3.1. Catalyst Materials and their ratio

A metal catalyst is necessary for the growth of the CNTs in all the methods used for synthesis of CNTs. Catalysts use to prepare CNTs usually include transition metals as a single or mixture of two catalysts such as a single, Fe, Co, Ni or Mo [53] or mixture of two catalysts such as FeNi [54], PtRh [55] and NiY [22]. Hsin et al. [57] firstly reported the production of metal-containing CNTs by arc discharge in solution.

The catalyst activation is determined in relation to the melting temperature and the boiling temperature thus the melting and boiling temperature of a catalyst can be one of the vital factors in the synthesis of SWCNTs [51].

CNTs are synthesized while the anode is filled by divergent single or bimetallic catalysts [51]. Scanning electron micros copies (SEM) show that the fabricated CNTs without any catalyst, figure 7, is in a very short long, disordered and is faulty grown.

Figure 7.

SEM image of the product which was fabricated without catalyst [51]

Figure 8.

SEM image of the product which is fabricated with 5% Ni as catalyst [51].

Ni catalyst, figure 8, motivate a production of elongated CNTs and springy CNTs with a relatively good yield while Fe catalysts, figure 9, promote a production of CNTs with short length and defect structure and the yield is moderate.

Figure 9.

SEM image of the product which was fabricated with 5% Fe as catalyst [51].

Jahanshahi et al. showed that Mo catalysts motivate a production of CNTs with long length and high crystalline structure but with a wide diameter while it has a relatively good yield. In contrast, Mo-Ni bimetallic catalyst cause the production of CNTs with long length, narrow distribution diameters and crystalline structure without any defect and follow with a good yield [51].

3.2. Plasma Solution Temperature

The effect of solution temperature on the synthesis of CNTs and the structure of fabricated CNTs was investigated by Dehghani et al [57]. Scanning electron microscopes and transient electron microscopes (TEMs), figure 10, shows that the fabricated CNTs below zero as thermal condition is not suitable for synthesizing CNTs by the arc discharge method in liquid and CNTs cannot grow under low temperatures, especially below zero. High temperature is also not suitable for synthesizing CNTs by the arc discharge method in liquid media.

In contrast, observations show that in the environment with (25 0C) temperature, long CNTs are formed with narrow distribution diameter, complete clean, flat surface and arranged structure. Constant temperature around 250C is the best thermal condition for synthesizing CNTs by the arc discharge method in liquid [57].

Figure 10.

SEM image of the product which was fabricated a) below zero temperature b) at a high temperature (800C), c) at the environment temperature (25 0C)[57].

3.3. Voltage difference between electrodes

The voltage effects on the production of the nanostructures by applying a variety of voltage values in different experiments were investigated by Jahanshahi et al [58]. The SEMs of the synthesized materials, figure 11 shows the formation of fullerene at a voltage of 10 V, while both CNTs and fullerenes are fabricated at a voltage of 20 V.

Figure 11.

a) SEM images of the produced sample by arc discharge at a voltage of 10 V. (b) SEM images of the produced sample by arc discharge at a voltage of 20 V. (c) SEM images of the produced sample by arc discharge at a voltage of 30 V [58].

On the contrary, the elongated CNTs were synthesized with high quality at a voltage of 30 V. The results show that the rate of production efficiency and anode consumption is increased by increasing the voltage amount [58].

3.4. Plasma Solution Concentration

Liquid nitrogen provides a good environment for the MWCN synthesis, but the strong evaporation cause by the operation of the arc discharge does not allow a good thermal exchange between the synthesized material and its surroundings.

Arc discharge in deionised water and liquid nitrogen are erratic due to their electrical insulation [50]. The electrical conductivity of LiCl solution is also better than deionised water and liquid nitrogen [59].

Figure 12 shows TEM image of the as-grown MWCN synthesized in LiCl. Investigators have demonstrated the possibility of producing carbon nanostructures in the liquid phase (water, hydrocarbons, dichloromethane, CCl4, in liquid gases) [61].

Figure 12.

TEM image of the as-grown MWCN synthesized in LiCl [58].

In contrast, liquid water besides providing a suitable environment also provides the thermal conditions necessary to retain good quality CNTs in the raw material, while the reactivity of the water with hot carbon does not appear to have any major effects on the reaction [59].

Figure 13 shows CNTs are produced in NaCl [62]. Nevertheless, arc discharge in NaCl solution is extremely stable owing to the excellent electrical conductivity induced by Cl- and Na+ ions. Too many Na+ ions would hinder carbon ions flying from anode towards the center of cathode. Researchers found that perhaps this is another reason that the length of SWCNT is short and only a single SWCNT [61].

Figure 13.

Production of CNTs in NaCl solution [62].

The optimized conditions to synthesize large quantities of SWCNT by applying arc discharge in NaCl solution deserve further investigation. Arc discharge in NaCl solution provides a very simple and cheap method to synthesize CNTs [60].

3.5. Discharge current

Discharge current is another important parameter influencing the products of arc discharge. If the catalyst percentage is 1 mol% Fe, and the discharge current is intentionally reduced to 20 A, the arc became very unstable, and disappear when the voltage is increased to 28 V [63].

3.6. The solution electrical conductivity effect

The effect of electrical conductivity of liquid on CNTs production might be important. A series of experiments carried out and the products were fabricated using arc discharge between two graphite electrodes submerged in different aqueous solutions of NaCl, KCl as well as LiCl. In comparative studies, CNTs were synthesized under different electrical conductivity conditions, and the results were analyzed, compared and discussed. The scanning electron microscopy (SEM), transmission electron microscopy (TEM) and Raman spectroscopy were employed to study the morphology of these carbon nanostructures and reported. LiCl 0.25 N (with 22.7mS as electrical conductivity) media when applied as solution, high-crystalline and a longed multi walled carbon nanotubes, single walled carbon nanotubes and springy carbon nanotubes (SCNTs) were synthesized. This study is one of the first one have demonstrated application of an arc discharge in liquid media with electrical conductivity effects upon CNT preparation and deserves further study (Dehghani and Jahanshahi, (2012); unpublished data).

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4. Purification of fabricated CNTs

CNTs usually contain a large amount of impurities such as metal particles, amorphous carbon, and multi shell. There are different steps in purification of CNTs. Purification of CNTs is a process that separates nanotubes from non-nanotube impurities included in the raw products, or from nanotubes with undesired numbers of walls. Purification has been an important synthetic effort since the discovery of carbon nanotubes, and there are many publications discussing different aspects of the purification process. Good review articles on the purification of CNTs are available in the recent literature [64, 65].

The current industrial methods applied oxidation and acid-refluxing techniques that affect the structure of tubes. Purification difficulties are great because of insolubility of CNT and the limitation of liquid chromatography.

CNT purification step (depending on the type of the purification) removes amorphous carbon from CNTs, improves surface area, decomposes functional groups blocking the entrance of the pores or induces additional functional groups.

Most of these techniques are combined with each other to improve the purification and to remove different impurities at the same time. These techniques are as follow:

4.1. Oxidation

Oxidation is a way to remove CNTs impurities. In this way CNTs and impurities are oxidized. The damage to CNTs is less than the damage to the impurities. This technique is more preferable with regard to the impurities that are commonly metal catalysts which act as oxidizing catalysts [66, 67].

Altogether, the efficiency and yield of the procedure are highly depending on a lot of factors, such as metal content, oxidation time, environment, oxidizing agent and temperature [67].

4.2. Acid treatment

Refluxing the sample in acid is effective in reducing the amount of metal particles and amorphous carbon. Different used acids are hydrochloric acid (HCl), nitric acid (HNO3) and sulphuric acid (H2SO4), while HCl is identified to be the ideal refluxing acid. When a treatment in HNO3 had been used the acid had an effect on the metal catalyst only, and no effects was observed on the CNTs and the other carbon particles. [66-69]. Figure 14 shows the SEM images of CNTs after and before purification stage with HCl [51].

If a treatment in HCl is used, the acid has also a little effect on the CNTs and other carbon particles [69, 70]. A review of literature demonstrates the effects that key variables like acid types and concentration & temperature have on the acid treatment [69, 70].

Figure 14.

The SEM images of CNTs (A) after (B) before purification stages with HCl [51].

4.3. Annealing and thermal treatment

High temperature has effect on the productions and paralizes the graphitic carbon and the short fullerenes. When high temperature is used, the metal will be melted and can also be removed [69].

4.4. Ultrasonication

This technique is based on the separation of particles due to ultrasonic vibrations and also agglomerates of different nanoparticles will be more dispersed by this method. The separation of the particles is highly dependable on the surfactant, solvent and reagents which are used [67-70].

When an acid is used, the purity of the CNTs depends on the sonication time. During the tubes vibration to the acid for a short time, only the metal is solvated, but in a more extended period, the CNTs are also chemically cut. [69].

4.5. Micro-filtration

Micro-filtration is based on particle size. Usually CNTs and a small amount of carbon nanoparticles are trapped in a filter. The other nanoparticles (catalyst metal, fullerenes and carbon nanoparticles) are passing through the filter [65, 69, 70, 72].

A special form of filtration is cross flow filtration. Through a bore of fiber, the filtrate is pumped down at head pressure from a reservoir and the major fraction of the fast flowing solution is reverted to the same reservoir in order to be cycled through the fiber again. A fast hydrodynamic flow down the fiber bore sweeps the membrane surface and prevents building up of a filter cake [67].

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5. Morphological and structural characterizations

To investigate the morphological and structural characterizations of the CNTs, a reduced number of techniques can be used. It is very important to characterize and determine the quality and properties of the CNTs, since its applications will require certification of properties and functions [74].

However, only few techniques are able to characterize CNTs at the individual level such as scanning tunneling microscopy (STM) and transmission electronic microscopy (TEM). X-ray photoelectron spectroscopy is required to determine the chemical structure of CNTs in spite of the fact that Raman spectroscopy is mostly introduced as global characterization technique.

5.1. Electron microscopy (SEM & TEM)

The morphology, dimensions and orientation of CNTs can be easily revealed by using scanning (SEM) and Transmission Electron Microscopes (TEM) which have high resolution. [70-75] (Figs. 15).

Therefore, the TEM technique is applied as a method for measurement of the outer and inner radius and linear electron absorption coefficient of CNTs [76].This method is used to study CNTs before and after annealing and notice a significant increase of the electron absorption coefficient. The inter shell spacing of MWNTs was studied by Kiang et al. [77] using high resolution TEM images.

Figure 15.

Electron micrographs of CNT (A) SEM of the CNT. (B) TEM of the CNT [57].

5.2. X-ray diffraction (XRD)

This technique is used to obtain some information on the interlayer spacing, the structural strain and the impurities. However, in comparing CNTs with x-ray incident beam, CNTs have multiple orientations. This leads to a statistical characterization of CNTs [78].

5.3. Raman spectroscopy

Raman spectroscopy is one of the most powerful tools for characterization of CNTs. Without sample preparation, a fast and nondestructive analysis is possible. All allotropic forms of carbon are active in Raman spectroscopy [79]. The position, width, and relative intensity of bands are modified according to the carbon forms [80].

A Raman spectrum of a purified sample (after applying the purification procedure) is shown in figure 16. The peaks at 1380 cm–1 and 1572 cm–1 correspond to disorder (D-band) and graphite (G-band) bands, respectively. The former is an indication of the presence of defective material and the latter one refers to the well-ordered graphite [62].

The most characteristic features are summarized as following:

  1. Low-frequency peak <200 cm-1 characteristic of the SWNT, whose frequency is depended on the diameter of the tube mainly (RBM: radical breathing mode).

  2. D line mode (disorder line), which is a large structure assign of residual ill-organized graphite.

  3. High-frequency bunch that is called G band and is a characteristic of CNTs. This bunch has the ability to be superimposed with the G-line of residual graphite [81].

Raman spectroscopy is considered an extremely powerful tool for characterizing CNT, which gives qualitative and quantitative information on its diameter, electronic structure, purity and crystalline, and distinguishes metallic and semiconducting material as well as chirality.

Figure 16.

Raman spectrum showing the most characteristic features of CNTs produced by arc discharge method in liquid followed by acid treatment [62].

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6. Conclusion

Carbon nanotubes (CNTs), a new structure of carbon element, are composed of graphen sheets rolled into closed concentric cylinders with diameter of the order of nanometers and length of micrometers. CNTs are attracted significant attention because of their unique physical and mechanical properties. These properties have been the engines of the rapid development in scientific studies in numerous applications such as in fuel cell and electrocatalyst, nanobiosensors, gas adsorptions and membrane separation [82-88].

Three methods, laser, arc discharge and chemical vapor deposition are used to synthesize CNTs. The laser method is also known as the laser-furnace method. The quantities CNTs in this method are large but this technique is not economically advantageous, since the process demanded considerable power. The chemical vapor deposition is another method for producing CNTs. It could produce CNTs at temperatures above 700 0C in large quantities, but the walls of the CNTs frequently contain many defects. Traditional arc discharge requires a complicated vacuum and heat exchange system. The yields of the laser and traditional arc discharge methods are very low (mg/h). From the application perspective, researchers are continuously trying to devise improved methods for CNTs fabrication.

Arc discharge in liquid media is a new method of synthesizing CNTs developed recently. All that is required is a dc power supply and an open vessel full of liquid nitrogen, deionized water or aqueous solution. This method is not requiring vacuum equipment, reacted gases, a high temperature furnace and a heat exchange system. Consequently, this method is extremely simple and cheap.

As it has been deeply investigated above, synthesis, purification and characterization of CNTs based on arc discharge in liquid media were described and discussed in this review paper. The observations of CNT growth under electron microscopy and other analytical techniques by different groups suggested that the mechanism are extremely sensitive to each fabrication parameter such as voltage difference between electrodes, current, type and ratio of catalysts, electrical conductivity, concentration, type and temperature of plasma solution and thermal conductivity. All these parameters were reviewed and studied herein. To the best of our knowledge the current review is the first one has discussed all aspects of arc discharge method in liquid media for CNT preparation and this technique deserves further attention.

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Acknowledgments

The authors are grateful to Prof. M. Shariaty Niasar (Tehran Uiversity, Iran), Prof. J. Raoof (The University of Mazandaran, Iran), Dr. H. Molavi and PhD student Mrs R. Jabari Sheresht for their previous collaborations and productive discussion during preparation of this paper.

References

  1. 1. Iijima S. 1991 Helical Microtubules of Graphitic Carbon. Nature 354 56 58
  2. 2. Dresselhaus M. S. Dresselhaus G. Eklund P. C. 1996 Science of fullerenes and carbon nanotubes. Academic Press New York
  3. 3. Dekker C. 1999 Carbon nanotubes as molecular quantum wires. Physics Today 52 22 30
  4. 4. Tans S. J. Verschueren A. R. M. Dekker C. 1998 Room-temperature transistor based on a single carbon nanotube. Nature 393 49 52
  5. 5. Javey A. Kim H. Brink M. Wang Q. Ural A. Guo J. Mc Intyre P. Mc Euen P. Lundstrom M. Dai H. 2002 Nature Materials 1 241 246
  6. 6. Javey A. Guo J. Wang Q. Lundstrom M. Dai H. J. 2003 Ballistic Carbon Nanotube Transistors. Nature 424 654 657
  7. 7. Rosenblatt S. Yaish Y. Park J. Gore J. Sazonova V. Mc Euen P. L. 2002 High Performance Electrolyte Gated Carbon Nanotube Transistors. Nano Letters 2 869 872
  8. 8. Lu C. Fu Q. Huang S. Liu J. 2004 Nano Letters 4 623
  9. 9. Huang S. M. Woodson M. Smalley R. Liu J. 2004 Growth Mechanism of Oriented Long Single Walled Carbon Nanotubes Using "Fast-Heating" Chemical Vapor Deposition Process. Nano Letters 4 1025 1028
  10. 10. Tan S. J. Devoret M. H. Dai H. J. Thess A. Smalley R. E. Geerligs L. J. Dekker C. 1997 Nature 386 474
  11. 11. Bockrath M. Cobden D. H. Mc Euen P. L. 2000 Individual Single-Wall Carbon Nanotubes As Quantum Wires. Science 290 1552 1555
  12. 12. Dai H. J. Hafner J. H. Rinzler A. G. Colbert D. T. Smalley R. E. 1996 Nanotubes As Nanoprobes in Scanning Probe Microscopy. Nature 384 147 150
  13. 13. Wong S. S. Harper J. D. Lansbury P. T. Lieber C. M. 1998 Am J. Chem. Soc. 120 603
  14. 14. Rinzler A. Hafner J. 1995 Unraveling Nanotubes- Field-Emission from an Atomic Wire. Science 269 1550 1553
  15. 15. Collins P. G. Bradley K. Ishigami M. Zettl A. 2000 Extreme oxygen sensitivity of electronic properties of carbon nanotubes. Science 287 1801 1804
  16. 16. Kong J. Franklin N. R. Zhou C. Peng S. Cho J. J. Dai H. 2000 Nanotube molecular wires as chemical sensors. Science 287 622 625
  17. 17. Chen R. J. Bangsaruntip S. Drouvalakis K. A. Kam N. W. S. Shim M. Li Y. M. Kim W. Utz P. J. H. Dai J. Natl P. 2003 Nanotube molecular wires as chemical sensors. Acad. Sci. USA 100 4984 4989
  18. 18. Star A. Gabriel J. C. P. Bradley K. Grüner G. 2003 Electronic detection of specific protein binding using nanotube FET devices. Nano Letters 3 459 463
  19. 19. Kuchta B. Firlej L. Pfeifer P. Wexler C. 2010 Numerical Estimation of Hydrogen Storage Limits in Carbon Based Nanospaces. Carbon 48 223 231
  20. 20. Scott C. Arepalli S. Nikolaev P. Smalley R. E. 2001 Applied Physics A: Materials Science & Processing 72 573 580
  21. 21. Bethune D. Kiang C. De Vries M. Gorman G. Savoy R. Beyer R. 1993 Nature 363 605 607
  22. 22. Journet C. Maser W. K. Bernier P. Loiseau A. Chapelle M. Lefrant S. Deniard P. Lee R. Fischer J. E. 1997 Large scale production of single wall carbon nanotubes by the electric arc technique. Nature 388 756 758
  23. 23. Cassell A. M. Raymakers J. A. Kong J. Dai H. 1999 Solvation of fluorinated single-wall carbon nanotubes in alcohol solvents. Journal of Physical Chemistry B 103 6484 6492
  24. 24. Liu J. Fan S. Dai H. 2004 MRS Bulletin 4 224 250
  25. 25. Jabari Seresht. R. Jahanshahi M. 2010 Fullerenes Nanotubes Carbon Nanostruct 2 1 12
  26. 26. Biró L. Horváth Z. Szalmás L. Kertész K. Wéber F. Juhász G. Radnóczi G. Gyulai J. 2003 Continuous carbon nanotube production in underwater ac electric arc. Chemical physics letters 372 399 402
  27. 27. Feng Y. Zhou G. 2003 Removal of some impurities from carbon nanotubes. Chemical physics letters 375 645 648
  28. 28. Guo T. Diener M. Chai Y. 1992 Uranium Stabilization of C28- a Tetravalent Fullerene. Science 257 1661 1664
  29. 29. Thess A. Lee R. 1996 Crystalline Ropes of Metallic Carbon Nanotubes Science 273 483 487
  30. 30. Bandow S. Rao A. 1997 Purification of single-wall carbon nanotubes by microfiltration. Journal of Physical Chemistry B 101 8839 8842
  31. 31. Chiang I. Brinson B. 2001 Journal of Physical Chemistry B 105 8297 8301
  32. 32. Ishii H. Kataura H. 2003 Direct observation of Tomonaga-Luttinger-liquid state in carbon nanotubes at low temperatures. Nature 426 540 544
  33. 33. Puretzky A. Geohegan D. 2000 Applied Physics A: Materials Science & Processing 70 153 160
  34. 34. Sen R. Ohtsuka Y. 2000 Time period for the growth of single-wall carbon nanotubes in the. Chemical physics letters 332 467 473
  35. 35. Kokai F. Takahashi K. 2000 Journal of Physical Chemistry B 104 6777 6784
  36. 36. Li Y. Mann D. 2004 Nano Letters 4 317 321
  37. 37. Walker P. Rakszawski J. 1959 Journal of Phys. Chem 63 133 140
  38. 38. Dresselhaus M. Dresselhaus G. 1988 Physical Properties of Carbon Nanotubes : Synthesis, Structure, Properties and Applications. Springer-Verlag Berlin
  39. 39. Endo M. 1988 Grow Carbon Fibers in the Vapor Phase. Chemtech 18 568 576
  40. 40. Baker R. T. K. Harris P. S. 1978 Marcel Dekker New York
  41. 41. Tibbetts G. G. 1984 Why are carbon filaments tubular? Journal of crystal growth 66 632 638
  42. 42. Seresht R. J. Jahanshahi M. Yazdani M. 2009 Parametric study on the synthesis of single wall carbon nanotube by gas arc-discharge method with multiple linear regressions and artificial neural network. International Journal of Nanoscience 8 243 249
  43. 43. Saito Y. Inagaki M. 1992 Yield of fullerenes generated by contact arc method under He and Ar-dependence on carbon nanotube. Chemical physics letters 200 643 648
  44. 44. Ebbesen T. Ajayan P. 1992 Nature 358 220 222
  45. 45. Belin T. Epron F. 2005 Characterization methods of carbon nanotubes: a review. Materials Science and Engineering B 119 105 118
  46. 46. Jahanshahi M. Raoof J. Hajizadeh S. Jabari Seresht. R. 2007 Nanotechnol. Appl. 929 71 77
  47. 47. Bera D. Johnston G. 2006 A parametric study on the nanotube structure through arc-discharge in water. Nanotechnology 17 1722 1730
  48. 48. Ishigami M. Cumings J. 2000 A simple method for the continuous production of carbon nanotubes. Chemical physics letters 319 457 459
  49. 49. Jung S. H. Kim M. R. 2003 Applied Physics A: Materials Science & Processing 76 285 286
  50. 50. Lange H. Sioda M. Huczko A. Zhu Y. Q. Kroto H. W. Walton D. R. M. 2003 Nanocarbon production by are discharge in water. Carbon 41 1617 1623
  51. 51. Jahanshahi M. Seresht R. J. 2009 Catalysts effects on the production of carbon nanotubes by an automatic arc discharge set up in solution. physica status solidi (c) 6 2174 2178
  52. 52. Xing G. Jia S. 2007 Influence of transverse magnetic field on the formation of carbon nanotube. Carbon 45 2584 2588
  53. 53. Xu B. Guo Ju. Wang X. Liu X. Ichinose H. 2006 Synthesis of carbon nanocapsules containing Fe, Ni or Co by arc discharge in aqueous solution. Carbon 44 2631
  54. 54. Seraphin S. Zhou D. 1994 Applied Physics Letters 64 2087 2089
  55. 55. Saito Y. Tani Y. 1998 High yield of single-wall carbon nanotubes by arc discharge using Rh-Pt mixed catalysts. Chemical physics letters 294 593 598
  56. 56. Hsin Y. L. Hwang K. C. Chen R. R. Kai J. J. 2001 Production and in-situ Metal Filling of Carbon Nanotubes in Water. J. Advanced Materials 13 830 833
  57. 57. Dehghani Kiadehi. A. Jahanshahi M. Mozdianfard M. R. Vakili-Nezhaad G. H. R. Jabari Seresht. R. 2011 Influence of the solution temperature on carbon nanotube formation by arc discharge method. Journal of Experimental Nanoscience 4 432 440
  58. 58. Jahanshahi M. Raoof J. Seresht R. J. 2009 Voltage effects on production of nanocarbons by a unique arc-discharge set-up in solution. Journal of Experimental Nanoscience 4 331 339
  59. 59. Lide D. R. 2003 CRC handbook of chemistry and physics; CRC Pr I Llc.
  60. 60. Wang Sh. Chang M. Lan K. M. Wu Ch. Cheng J. Chang H. 2005 Carbon 43 1778 1814
  61. 61. Schur D. V. Dubovoy A. G. Zaginaichenko S. Yu Adejev. V. M. Kotko A. V. Bogolepov V. A. Savenko A. F. Zolotarenko A. D. 2007 Carbon 45 1322 1329
  62. 62. Jahanshahi M. Raoof J. Hajizadeh S. Seresht R. J. 2009 Synthesis and subsequent purification of carbon nanotubes by arc discharge in NaCl solution. Phys. Status Solidi A 1 101 105
  63. 63. Wang S. D. Chang M. H. Cheng J. J. Chang H. K. Lan K. M. D. 2005 Carbon 43 1317 1339
  64. 64. Park T. J. Banerjee S. Hemraj-Benny T. Wong S. S. 2006 Mater J. Chem.16 141 154
  65. 65. Haddon R. C. Sippel J. Rinzler A. G. Papadimitrakopoulos F. 2004 Purification and separation of carbon nanotubes. MRS Bull. 29 252 259
  66. 66. Hajime G. Terumi F. Yoshiya F. Toshiyuki O. 2002 Method of purifying single wall carbon nanotubes from metal catalyst impurities. Honda Giken Kogyo Kabushiki Kaisha, Japan.
  67. 67. Borowiak-Palen E. Pichler T. 2002 Chemical physics letters 363 567 572
  68. 68. Farkas E. Anderson M. E. Chen Z. H. Rinzler A. G. 2002 Length sorting cut single wall carbon nanotubes by high performance liquid chromatography. Chem. Phys. Lett. 363 111 116
  69. 69. Kajiura H. Tsutsui S. Huang H. J. Murakami Y. 2002 High-quality single-walled purification from arc-produced soot. Chem Phys Lett. 364 586 92
  70. 70. Chiang I. Brinson B. 2001 Journal of Physical Chemistry B 105 8297 8301
  71. 71. Bandow S. Rao A. 1997 Journal of Physical Chemistry B 101 8839 8842
  72. 72. Moon J. M. An K. H. 2001 High-yield purification process of singlewalled carbon nanotubes. Journal of Physical Chemistry B 105 5677 5681
  73. 73. Jahanshahi M. Tobi F. Kiani F. 2005 Carbon-Nanotube Based Nanobiosensors: Electrochemical Pretreatment. The 10th Iranian Chemical Engineering Conference, Zahedan, Iran
  74. 74. Mawhinney D. B. Naumenko V. Kuznetsova A. Yates J. T. Liu J. Smalley R. E. 2000 Surface defect site density on single walled carbon nanotubes by titration. Chem. Phys. Lett. 324 213 216
  75. 75. Li W. Wen J. Tu Y. 2001 Ren Z. Appl. Phys. A73 259 264
  76. 76. Gommes C. Blacher S. 2003 Carbon 41 2561 2572
  77. 77. Kiang C. H. Endo M. 1998 Size effect in carbon nanotubes. Physical review letters 81 1869 1872
  78. 78. Zhu W. Miser D. Chan W. Hajaligol M. 2003 Mater. Chem. Phys 82 638 647
  79. 79. Arepalli S. Nikolaev P. 2004 Protocol for the characterization of SWCNT material quality. Carbon 42 1783 1791
  80. 80. Ferrari A. Robertson J. 2000 Physical Review B 61 14095
  81. 81. Hiura H. Ebbesen T. W. Tanigaki K. Takahashi H. 1993 Single-walled carbon nanotubes produced by electric arc. Chem. Phys. Lett. 202509
  82. 82. Raoof J. B. Jahanshahi M. Momeni Ahangar. S. 2010 Nickel Particles Dispersed into Poly (o-anisidine) and Poly (oanisidine)/Multi-walled Carbon Nanotube Modified Glassy Carbon Electrodes for Electrocatalytic Oxidation of Methanol. Int. J. Electrochem. Sci. 5 517 530
  83. 83. Toubi F. Jahanshahi M. Rostami A. A. Hajizadeh S. 2009 Voltametric tests on different carbon nanotubes as nanobiosensor devices. D. Biochem Process Biotech. Mol. Biol. 2 71 74
  84. 84. Khalili S. Ghoreyshi A. A. Jahanshahi M. 2012 Equilibrium, kinetic and thermodynamic studies of hydrogen adsorption on multi-walled carbon nanotubes. Iranica Journal of Energy & Environment 1 69 75
  85. 85. Delavar M. Ghoreyshi A. A. Jahanshahi M. Khalili S. Nabian N. 2012 The effect of chemical treatment on adsorption of natural gas by multi-walled carbon nanotubes: sorption equilibria and thermodynamic studies. Chemical Industry & Chemical Engineering Quarterly Inpress.
  86. 86. Delavar M. Ghoreyshi A. A. Jahanshahi M. Nabian N. 2012 Journal of Experimental Nanoscience Inpress.
  87. 87. Delavar M. Ghoreyshi A. A. Jahanshahi M. Khalili S. Nabian N. 2012 Equilibria and kinetics of natural gas adsorption on multi-walled carbon nanotube material. Green Chemistry2 4490 4497
  88. 88. Rahimpour A Jahanshahi M Khalili S Mollahosseini A Zirepour A Rajaeian B 2012 Novel functionalized carbon nanotubes for improving the surface properties and performance of polyethersulfone (PES) membrane. J. Desalination. 286 99 107

Written By

Mohsen Jahanshahi and Asieh Dehghani Kiadehi

Submitted: 15 June 2012 Published: 09 May 2013

© 2013 The Author(s). Licensee IntechOpen. This chapter is distributed under the terms of the Creative Commons Attribution 3.0 License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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