Abstract
Carbon nanotubes (CNTs) have attracted significant interest due to their unique combination of properties including high mechanical strength, large aspect ratios, high surface area, distinct optical characteristics, high thermal and electrical conductivity, which make them suitable for a wide range of applications in areas from electronics (transistors, energy production and storage) to biotechnology (imaging, sensors, actuators and drug delivery) and other applications (displays, photonics, composites and multi-functional coatings/films). Controlled growth, assembly and integration of CNTs is essential for the practical realization of current and future nanotube applications. This review focuses on progress to date in the field of CNT assembly and integration for various applications. CNT synthesis based on arc-discharge, laser ablation and chemical vapor deposition (CVD) including details of tip-growth and base-growth models are first introduced. Advances in CNT structural control (chirality, diameter and junctions) using methods such as catalyst conditioning, cloning, seed-, and template-based growth are then explored in detail, followed by post-growth CNT purification techniques using selective surface chemistry, gel chromatography and density gradient centrifugation. Various assembly and integration techniques for multiple CNTs based on catalyst patterning, forest growth and composites are considered along with their alignment/placement onto different substrates using photolithography, transfer printing and different solution-based techniques such as inkjet printing, dielectrophoresis (DEP) and spin coating. Finally, some of the challenges in current and emerging applications of CNTs in fields such as energy storage, transistors, tissue engineering, drug delivery, electronic cryptographic keys and sensors are considered.
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Introduction
Carbon nanotubes (CNTs) are long, hollow cylindrical tubule structures made of graphite sheets (a.k.a. graphene), with diameters ranging from below 1 nm to 10 s of nm [1]. CNTs exhibit different electronic properties based on the way these graphene layers are rolled into a cylinder. Nanotubes could either be single-walled structures, called single-walled carbon nanotubes (SWCNTs) or could have many walls, called multi-walled carbon nanotubes (MWCNTs). SWCNTs can be further categorized electrically into semiconducting and metallic SWCNTs (s-SWCNTs and m-SWCNTs), while MWCNTs mainly display metallic behavior. The novel and useful properties of CNTs, such as low-cost, light-weight, high aspect ratios and surface area, distinct optical characteristics, high thermal and electrical conductivity and high mechanical strength make them suitable and of interest for a wide range of electronic, biomedical and other industrial applications. For example, CNTs are promising for electronics ‘beyond CMOS’ as active devices and interconnects in future integrated circuits [2].
CNTs are part of the fullerene family, which are a group of carbon allotropes with atoms linked in the shape of cage-like structures such as a hollow sphere, ellipsoid or cylindrical tube [3]. Fullerenes are comprised of graphene sheets of linked hexagonal and pentagonal rings, which give them their curved structure. Graphene is an allotrope of carbon, which is comprised of a single layer of carbon atoms, arranged in a two-dimensional hexagonal lattice. It is a semi-metal, which has an overlap between the valence and conduction bands, i.e. it has a zero-bandgap [1]. The buckminsterfullerene (buckyball/C60), one of the most common spherical fullerenes, is a nanoscale molecule having 60 carbon atoms, with each atom being bonded to three other adjacent atoms to form hexagons and pentagons, with the ends curved into a sphere. The C70 molecule is another spherical fullerene that is known for being chemically stable. Additionally, other smaller metastable species, such as C28, C36 and C50, have been discovered. It is believed that fullerenes have existed in nature for a long time; minute quantities of fullerenes in the form of C60, C70, C76, C82 and C84, have been found hidden in soot [3, 4]. Nanotubes are comprised of sp2-hybridized carbon bonds, which are stronger than the sp3-hybridized carbon bonds found in diamond, thereby making for the exceptional strength and stiffness of nanotubes. Additionally, they are known to possess very high electrical conductivity [5, 6], high charge carrier mobility [7], high chemical stability [8, 9], large specific surface ratio [10], high aspect ratio [11], excellent mechanical properties [12, 13] and excellent heat conductivity [14], with some SWCNTs exhibiting superconductivity [15, 16]. These properties make CNTs an important topic in nanoscience and electronics research [17].
The specific surface area (SSA) of an individual SWCNT has been theoretically obtained as 1315 m2 g−1; but measured surface areas are much lower due to bundling, agglomeration and purity of the tubes [10]. For example, SWCNT specimens with SSA values between 150 and 790 m2 g−1 have been obtained [10]. For MWCNTs, the number of walls is the predominant parameter which determines the SSA. Some measured SSA values include 680–850 m2 g−1 for two-walled CNTs and 500 m2 g−1 for three-walled CNTs [10]. Additionally, CNTs have noteworthy mechanical properties. The elastic modulus for individual MWCNTs is about 1 TPa, while the tensile strength for MWCNTs ranges from 11 to 63 GPa [12, 13]. On the other hand, for single SWCNTs, tensile strength values of about 22 GPa have been obtained [12]. Young’s modulus of individual SWCNTs was directly measured and estimated to be between 0.79 and 3.6 TPa [12, 13, 18] while for individual MWCNTs, values of between 0.27 and 2.4 TPa were obtained [12, 19]. The compressive strength of thin MWCNTs was estimated to be between 100 and 150 GPa [20]. CNTs also have good thermal properties. Individual SWCNTs can have thermal conductivity values between 3500 and 6600 W m−1 K−1 at room temperature, which exceeds the thermal conductivity of diamond [14, 21], while the thermal conductivity of individual MWCNTs ranges from 600 to 6000 W m−1 K−1 [21]. CNTs also have interesting dimensional properties. Their aspect ratio (length-to-diameter) values can be extremely high. Typical CNT diameter values vary from 0.4 to 40 nm (i.e. by about 100 times), but the length can vary by 10,000 times, reaching 55.5 cm, thus the aspect ratio can be very high [11].
CNTs also have unique electronic properties. CNTs’ distinct electronic properties are inherently related to their unique, low-dimensional band structure and quantum-confined carriers. SWCNTs can be either metallic or semiconducting, depending on the diameter and orientation of the graphene lattice with respect to the tube axis, termed as the chirality of the tube [1, 22]. Basis vectors a1 and a2 determine the graphene lattice. The chiral vector (C), which corresponds to the side of the graphene sheet that will eventually become the CNT circumference is given by: C = na1 + ma2, where the n and m are integers. The graphene sheets can be rolled in different ways to generate the three different classes of SWCNTs, as shown in Fig. 1a–c. Also, the electronic properties of each CNT arise from the geometry of the tube, dictated by its chiral vectors. If m = 0, C lies along either a1 or a2 and the nanotubes will be referred to as zigzag CNTs, while if n = m, C lies along the direction exactly between a1 and a2 and the tubes are referred to as armchair nanotubes. Finally, chiral nanotubes are formed when n ≠ m. Figure 1b shows how the different types of CNTs based on the chiral indices and the corresponding chiral angles are defined. Analysis within the so-called zone-folding scheme [23] shows that armchair tubes are always metallic while two-thirds of zigzag tubes are semiconducting. More generally, two-thirds of all SWNTs are predicted to be semiconducting with the rest metallic or possessing a small band gap (quasi-metallic).
CNTs have extremely high charge carrier mobility, and as such, they have the potential to be considered for various electronic device applications [24]. Much progress has been made showing that SWCNTs are advanced quasi-one-dimensional (1D) materials, with high carrier mobility. Estimated values of the carrier mobility in CNTs range from 20 cm2 V−1 s−1 [7] to very large values (~ 104 or greater) in semiconducting tubes and ballistic in metallic tubes [25]. Current densities of between 107 A cm−2 and 108 A cm−2 are achievable for SWCNTs, with SWCNTs being able to pass currents of about 20 μA [26]. Ballistic SWCNTs with have shown resistances between 6.5 and 15 kΩ. MWCNTs are typically metallic [1], and have a very high current-carrying capacity ranging from 106 to 109 A cm−2 [26, 27]. The bandgap of a semiconducting CNT has been shown to be inversely proportional to its diameter (Fig. 2a), and is given by Egap = 2γ0aC-C/d, where yo represents the C-C tight binding overlap energy (2.45 eV), aC-C is the nearest neighbor C-C distance (0.142 nm) and d is the diameter of the tube [28, 29]. For example, semiconducting CNTs with a radius of 0.2 nm have band gaps of about 2.2 eV, while tubes with a radius of 1.4 nm have band gaps of about 0.4 eV [30].
Each CNT has a distinct optical property because the wave function boundary condition alters with the (n, m) indices or chirality of the tube. Thus, optical properties such as absorption, photoluminescence and Raman spectroscopy can be used to extensively carry out quick and non-destructive studies of CNTs, by probing CNT samples with photons [31,32,33]. CNTs also exhibit unique photo-ignition properties when exposed to light [34, 35], resulting in the generation of an acoustic wave and oxidation of the CNTs. The results of optical spectroscopies can be recorded by a Kataura plot, in which each point represents the optical transition energy Eii (i = 1, 2, 3, ...) for a specific (n, m) SWCNT plotted as a function of the tube diameter as shown in Fig. 2a. 1D crystals do not have their density of states (DOS) as a continuous function of energy, but have a spike-like DOS, which rises and falls in a discontinuous spike. These sharp spikes or Van Hove singularities (VHS) make for the unique optical properties of CNTs [32]. Optical absorption in CNTs is different from absorption in most bulk materials due to the presence of sharp peaks. When SWCNTs absorb light, the electrons in the VHS of the valence band are elevated to the corresponding energy levels in the conduction band. In nanotubes, optical absorption is tied to the sharp electronic transitions from the v2 to c2 (energy E22) or v1 to c1 (E11) levels (Fig. 2b) [36]. These transitions are probed and are then used to identify nanotube types [32].
Apart from optical absorption properties of CNTs, another optical property that is typically studied is its photoluminescence. Photoluminescence is used to measure the quantities of semiconducting nanotube species in a sample of CNTs. Semiconducting SWCNTs emit near-infrared light when excited by a photon, a property referred to as photoluminescence [37]. When an electron in a semiconducting SWCNT absorbs excitation light, resulting in an E22 transition (electronic transition from the valence to conducting band in a semiconducting SWCNT), an electron-hole pair is created. Both the electron and hole rapidly relax, from c2 to c1 and from v2 to v1 states, respectively. Finally, they recombine through a c1 − v1 transition resulting in light emission [32]. No excitonic luminescence can be produced in metallic tubes—although they can produce electron-hole pairs, the holes are immediately filled by other electrons out of the many available in the metal and hence no excitons are produced.
Raman spectroscopy, another optical technique for CNT characterization, has the ability to detect semiconducting as well as metallic tubes [38] and via Raman microscopy can provide good spatial resolution as well. In Raman spectroscopy, a photon is used to excite a sample of CNTs and is scattered by the phonons in the sample. An analysis of the change in frequency between the exciting photon and the released photon tells what kind of CNTs are in a sample, mainly via the diameter-dependent radial breathing mode [23]. Raman scattering in SWCNTs can also be resonant, meaning that only tubes which have one of the bandgaps equal to the exciting laser energy are selectively probed with an enhanced absorption cross-section.
Selected numerical data for the CNT properties described above are listed in Table 1:
Due to their unique and desirable properties, CNTs have found many applications and incorporation into several commercial products to date.
Semiconducting CNTs have been used in field-effect transistors (FETs) [7, 45,46,47,48] (Fig. 3 shows the schematic and I-V characteristics of a CNT field-effect transistor (CNTFET) exhibiting switching for different gate voltages); metallic CNTs are used as interconnects [49, 50]; both single-walled and multi-walled nanotubes have also been used in various THz applications (described below) and Schottky diodes [51]. CNTs are currently being used in lithium ion batteries for efficient energy storage [52, 53]; hydrogen fuel cells [54] and CNT coatings have been extensively used to sense gases like ammonia, hydrogen and methane [55]. Super-aligned carbon nanotube films have been used in liquid crystal displays (LCDs) [56]; CNTs have also found applications in transparent conductive films [57].
CNT-material composites have been found to have enhanced properties. For example, CNT-reinforced epoxy composites were found to have a 24.8% increase in tensile strength compared to the pure epoxy matrix [58]. Additionally, by introducing a small amount of magnetically aligned CNTs into carbon fiber reinforced polymer composites, the flexural modulus and load-carrying capacity were increased by 46% and 33%, respectively [59]. Also, thermoplastic polyurethane (TPU)-based composites filled with CNTs and intumescent flame retardants were shown to achieve good flame retarding, prompt self-extinguishment, good electromagnetic interference shielding properties and increased electrical conductivity [60]. In addition, mixing CNT powders with polymers would increase stiffness, strength and toughness for load-bearing applications [61, 62]. MWCNTs—magneto-fluorescent carbon quantum dots, a carbon nanotube-composite, has been used as a carrier for targeted drug transport in cancer therapy [63]; nanofluids, containing dispersed CNTs, show enhanced heat transfer characteristics [64]; and nitrogen-doped CNTs (N-CNTs) can be used as adsorbents in food analysis, to trace bisphenols in fruit juices [65].
Researchers have begun using SWCNTs as building blocks of novel high-frequency devices [66]. In the presence of external magnetic fields and electric fields, certain nanotubes develop strong terahertz (THz) optical transitions, thus making them useful as tunable, optically active materials in THz devices. Several proposals for using CNTs in THz applications have been developed. They include a nanoklystron which utilizes efficient high-field electron emission from nanotubes, devices based on negative differential conductivity in large-diameter semiconducting nanotubes as well as single and multi-wall carbon nanotube antennae operating in the THz regime [66,67,68]. Due to their unique electronic properties, CNTs are being used as sources of terahertz (THz) radiation. Creating a compact, reliable source of THz radiation is very important for contemporary applied physics, as there are no miniaturized and low-cost THz sources currently available [66,67,68]. THz radiation lies between the microwave and infrared radiation in the electromagnetic spectrum. In this frequency range, electronic transport and optical phenomena merge with one another, and classical waves become quantum mechanical photons. This unique position of the THz range means they can only be studied by novel approaches which bridge the gap between the electronic and optical properties of materials, such as by using carbon-based nanomaterials. Researchers are also investigating the use of CNTs in fields including photovoltaics [69] and infrared (IR) detection [70].
The possibility of using CNTs as reactors for synthesis at the nanoscale is another area being explored [71]. Use of CNTs as catalyst supports for electrocatalytic oxygen reduction reactions (ORR) and oxygen evolution reactions (OER) is gaining widespread popularity [72,73,74,75,76]. In particular, various studies have shown the use of nitrogen-doped carbon nanomaterials for efficient ORR and OER reactions, where these CNT electrodes have demonstrated improved stability and electrocatalytic activity as compared to metals like platinum [76, 77].
In general, precise control of the placement, type, orientation and/or structure of large numbers of CNTs is needed in order to optimize their performance for a given application such as those mentioned above. In this review, progress in carbon nanotube assembly and integration based on a variety of approaches will be reviewed and discussed. In particular, we first focus on techniques for controlling individual CNTs, both directly during growth, and via post-growth approaches. We then examine methods that have been developed for the integration of large numbers of nanotubes in parallel along with the resulting structures and ensembles. Lastly, despite tremendous progress over the past two decades in CNT fabrication and assembly, we highlight significant challenges that remain for both current and emerging applications using CNTs. A schematic outline of this paper is shown in Fig. 4.
Controlling Individual CNTs
CNT Growth—Overview
The most widely known techniques for fabrication of CNTs are arc-discharge, laser ablation and chemical vapor deposition. The carbon atoms that result in the formation of CNTs are liberated by methods utilizing current (in arc-discharge), high intensity laser (in laser ablation) and heat (in CVD). These techniques are discussed briefly in the following sections.
Arc-Discharge
CNTs were produced from carbon soot of graphite electrodes using the arc-discharge method [78]. Arc-discharge method employs high temperature (over 1700 °C) for synthesizing CNTs. This method consists of two graphite electrodes, an anode and cathode (with diameters of 6 mm and 9 mm) which are placed approximately 1 mm apart in a large metal reactor as shown in Fig. 5 [79]. While maintaining an inert gas at a constant high pressure inside the metal reactor, a direct current of ~ 100 A is applied with a potential difference of ~ 18 V [80]. When the two electrodes are brought closer, a discharge occurs leading to the formation of plasma. A carbonaceous deposit which contains nanotubes is formed on the larger electrode. MWCNTs in the form of carbon soot of 1 nm to 3 nm inner diameter; and ~ 2 nm to 25 nm outer diameter were observed to be deposited in the negative electrode [1, 78]. By doping the anode with metal catalysts such as Cobalt (Co), Iron (Fe) or Nickel (Ni), and using pure graphite electrode as the cathode, SWCNTs could be grown up to a diameter of approximately 2 nm to 7 nm [81,82,83]. This technique can be used to grow large quantities of SW/MWCNTs. However, the major drawback of this technique is the limited yield quantity due to the use of metal catalysts that would introduce unwanted post-reaction products which need purification.
Laser Ablation
This technique is similar to the arc-discharge technique; however, it employs a continuous laser beam, or a pulsed laser as shown in Fig. 6 [84] instead of arc-discharge. The laser beam vaporizes a large graphite target in the presence of an inert gas such as He, Ar, N2 etc. in a quartz tube furnace at ~ 1200 °C. Then, the vaporized carbon condenses and CNTs are self-assembled on the cooler surface of the reactor [85,86,87,88]. If both electrodes are made of pure graphite, MWCNTs are produced with an inner diameter of ~ 1 nm to 2 nm and an outer diameter of approximately 10 nm [89]. When the graphite target is doped with Co, Fe or Ni, the resultant deposit was observed to be rich in SWCNT ‘ropes’ or bundles (Fig. 1e). The yield and quality of CNTs produced depends on the growth environment such as laser properties, catalyst composition, growth temperature, choice of gases and pressure. This method can be expensive due to the need for high-power laser beams. One advantage of this technique is that post-growth purification is not as intensive as in arc-discharge method due to less impurities.
Chemical Vapor Deposition
Chemical vapor deposition (CVD) is commonly termed as catalytic chemical vapor deposition (c-CVD) due to the use of metal catalysts in the thermal decomposition of a hydrocarbon vapor. Catalysts play a very important role in the growth of CNTs. An ideal catalyst should be monodispersed on the surface of the substrate. It should also interact with the substrate appropriately via Van der Waals forces. Growth efficiency of the SWCNTs can be improved when there is a weak interaction between the catalyst and the substrate. At high temperatures, metal catalysts are very unstable and chirality-controlled growth of the SWCNTs becomes a challenging task. An ideal catalyst should offer good stability at higher temperatures and lead to controlled growth of CNTs with better diameter distribution. By increasing the interactions between catalyst support and the catalyst nanoparticles, control over some of the problems encountered at high temperatures may be achieved. Hydrocarbon sources may be in liquid (benzene and alcohol), vapor (carbon monoxide) or solid form (camphor) [79]. For the decomposition of hydrocarbons, nanometer-sized transition metal catalysts such as Fe, Co, Ni, Mo are commonly used [90,91,92]. In addition, metal catalysts like Cu, Au, Ag and Pt have also been used in some studies [93]. In some cases, these metal catalysts are mixed with catalyst supports such as SiO2, MgO and Al2O3 in order to increase the surface area of the catalytic reaction involving the carbon feedstock and the metal particles [94].
The choice of the type of hydrocarbons and catalysts used determines the various growth mechanisms, termed as vapor-liquid-solid (VLS) or vapor-solid-solid (VSS) mechanisms. Of the two, the VLS mechanism is widely used. Here, the catalyst particles are in the liquid phase, where hydrocarbons are adsorbed on the metal particles and are catalytically decomposed. Next, the carbon forms a liquid eutectic by dissolving into the particle and later precipitates in to a tubular form upon super-saturation [95, 96]. On the other hand, VSS growth mechanism uses a solid catalyst [97].
The synthesis method begins with decomposition of a hydrocarbon vapor in the presence of a metal catalyst at a temperature of ~ 600–1200 °C [98, 99]. When the hydrocarbon vapor interacts with the metal, it decomposes into carbon and hydrogen. Carbon gets dissolved into the metal while the hydrogen gas evaporates. Then, based on the catalyst-substrate interactions, growth of CNTs on the metal catalyst is either in the form of a tip-growth mechanism or a base-growth mechanism [100, 101] as shown in Fig. 7. Tip-growth mechanism is due to weak catalyst–substrate interaction. Here, the hydrocarbon decomposes on the top of metal while the carbon starts to diffuse through the metal. The CNT starts growing from the base of the metal and continues to grow longer till there is enough room for additional hydrocarbon decomposition based on the metal’s concentration gradient. In this process, the metal is pushed farther away from the substrate as shown in Fig. 7a. In case of a base-growth mechanism, there is a strong catalyst–substrate interaction. Similar to tip-growth mechanism, the hydrocarbon decomposes on the top of metal while the carbon starts to diffuse through the metal. However, due to strong catalyst-substrate interaction, the metal particle is not pushed higher, and the CNT grows on top of the metal as shown in Fig. 7b. Figure 8 shows examples of CNTs grown via CVD [102, 103].
Size and properties of the catalyst play a significant role in the growth of SWCNTs and MWCNTs using CVD. Smaller particle size (a few nm) leads to the growth of SWCNTs, whereas MWCNTs are formed when the particle size is larger (tens of nm) [1]. The type of hydrocarbons influences the shape of the CNTs produced. For example, methane, acetylene which are linear hydrocarbons, lead to formation of straight hollow CNTs. Cyclic hydrocarbons like benzene and fullerene produce curved CNTs [104].
In addition, the choice of substrate used also plays an important role in the growth of CNTs due to the catalyst–substrate interactions, in turn influencing the yield, quality and aspect ratio of the CNTs produced. Some of the commonly used substrates for growth of CNTs are made of materials like silicon [104], graphite [18], alumina [105, 106] and zeolite [107]. Studies have shown that use of zeolite substrates can result in high yields with narrow diameter distribution and that substrates made of alumina produce high yields of aligned CNTs with high aspect ratio [79, 108].
Along with the catalyst and substrate choices, structural control of individual CNTs is also affected by the temperature and the gas flow rate during the synthesis procedure. Control of gas flow rate during synthesis depends on the type of hydrocarbons used (i.e. gaseous, solid or liquid. An increase in the SW/MWCNT’s diameter is observed with an increase in the synthesis temperature [109]. For example, in case of a Fe–Co–zeolite system with camphor, the ideal temperature for SWCNT growth was reported to be around 900 °C, whereas for MWCNTs, the ideal growth temperature was reported to be 650 °C [100].
Of the three CNT manufacturing techniques discussed in this section, CVD is a widely used technique to manufacture CNTs due to its various advantages such as better controllability over CNT growth, low cost and use of low temperature [79, 105].
Structural Control of Individual CNTs
Chirality Control
Growing CNTs with controllable chirality is an important step in order to utilize them for various applications. This is because the chirality of a CNT determines various properties like electronic band structure and thus, the type of CNTs grown (i.e. metallic vs. semiconducting). Chirality control can be done by direct-controlled growth or post-synthesis separation approaches or by combining these methods [110] and is considered as one of the most challenging aspects in CNT growth [111]. Various parameters such as growth temperature, catalyst and hydrocarbon type influence the chirality of the CNTs. Direct controlled growth methods aim at controlling the chirality by controlling the nucleation process, as it is reported that during the nucleation process, chirality of a SWCNT is fixed [112]. For example, plasma-enhanced CVD (PECVD) has been used for the preferential growth of semiconducting SWCNTs [113]. In addition, semiconducting CNTs were also grown using ST-quartz substrates and methanol precursors [114]. Various growth parameters like type of catalyst, growth temperature and pressure and the source of the hydrocarbons play a significant role in influencing the nucleation which in turn controls the chirality of the tubes grown. Some of the techniques like use of CNT growth templates as seeds (both metal-based and non-metal based), growth initiated by carbon molecular-based precursors and use of nanoparticle-based catalysts have gained a great interest in this field. Some of these are discussed below:
In the first technique we describe, a single (n, m)-type SWCNT nanotube sample is cut into smaller pieces (seeds), each of which was aimed to be used as a template for the growth of a longer nanotube using a VLS amplification process (Fig. 9a). The main goal of this method was to grow large quantities of n, m-controlled structures. Each seed was polymer-wrapped SWCNT, end-carboxylated and tethered with Fe salts at its ends. During the growth process, Fe salts acted as growth catalysts and use of VLS mechanism aimed at achieving narrow diameter distribution [115]. SWCNTs grown with this method had a diameter similar to the diameter of the growth seed (Fig. 9b–f). However, details about the modifications in chirality of the tubes grown could not be clearly established [116]. In addition, this method also involves the need for complex purification steps due to the presence of metallic particles in the SWCNTs grown, thus affecting the final product’s quality.
As an alternative to metal-catalyst-based growth, another technique involved the controlled growth of CNTs by using semiconductor nanoparticles like Si and Ge as the growth templates. In one of these experiments, CNTs were grown using semiconducting nanoparticles (of size 5 nm or smaller), by introducing thermally decomposed carbon atoms from ethanol at 850 °C. However, CNTs grown in this experiment were considered to be of very low quality and low yield as compared to experiments using Fe, Co or Ni as catalysts [117]. Another growth technique was via an open-end growth mechanism, commonly referred as ‘cloning’ (Fig. 10) [118]. Here, the chirality of the SWCNTs was controlled by using open-end SWCNTs as seeds/catalysts without using a separate metal catalyst. Using these seeds, duplicate CNTs were grown on a SiO2/Si substrate. The total yield reported in this method was ~ 9%, which could be improved to 40% by growing SWCNTs using this method on a quartz substrate [118]. Another technique based on vapor-phase epitaxy was used to grow the SWCNTs with predefined chirality. This method combined CVD and SWCNT separation techniques by using deoxyribonucleic acid (DNA)-separated single chirality SWCNT seeds as the growth templates. These seeds were of very high purity (~ 90%) and C2H5OH and CH4 were used as the carbon sources. This experiment showed significant elongation of the SWCNTs grown from a few 100 nm to tens of microns. The total yield produced in this method was very low [110] and some of the studies related to vapor phase epitaxy (VPE)-based growth techniques are ongoing with aims to improve the yield.
One way to selectively grow chiral SWCNTs is by using silica substrate and Co-Mo catalyst [119]. Nanotubes of (6,5) and (7,5) chirality were obtained in this technique. With proper interaction between the Co and Mo oxides, aggregation of Co nanoparticles at high temperatures could be avoided. In addition, by optimizing the gaseous feed composition, growth and temperature, selectivity of (6,5) nanotubes was improved by ~ 55% [120]. Another approach for the selective growth of (6,5) SWCNTs was demonstrated using Co-Si catalyst and provided narrow distribution chiral SWCNTs [121]. High quality (6,5) tubes have also been grown at 800 °C using atmospheric pressure alcohol CVD on silica-bimetallic CoPt catalysts with narrow chirality distribution by tailoring the catalyst composition [122]. (9,8) SWCNTs were grown with high selectivity using Co nanoparticles and nanoporous Si support (TUD-1) [123]. Recently, (12,6) SWCNTs were synthesized using tungsten-based bimetallic solid alloy catalyst, W6Co7, with purity of > 92% (Fig. 11) [124]. This high level of purity was attributed to the W6Co7 catalyst which has a very high melting point of 2400 °C and provides a potential avenue for the growth of high purity SWCNTs by using nanoparticle catalysts.
Recently, selective growth of semiconducting SWCNT with diameters in the range of 0.8–1.2 nm was reported based on the deactivation process of the catalyst using a technique known as ‘catalyst conditioning process’ [125]. Here, the catalysts favoring the growth of metallic SWCNT are exposed to the catalyst conditioning parameters (oxidative, i.e. water) and reductive (i.e. H2) gases prior to the growth process which leads to the deactivation of these catalysts. An inverse relationship between yield and selectivity based on catalyst deactivation was reported in this work.
Evolving methodologies in the field of organic chemistry have enabled the synthesis of various carbon-based precursors that could be used in growing CNTs with controlled chirality. Some of the examples include flat CNT end-caps, three-dimensional CNT end-caps and carbon nanorings [111, 126, 127], which have all been tested and have proved to stimulate CNT growth under controlled environment. However, each of these approaches has some limitations [128].
In one method, in order to yield hemispherical caps, thermal oxidation was used to open fullerndione. However, there were challenges in the synthesis of single chirality CNTs due to the lack of control in the formed hemispherical cap structures [129]. Synthesis of CNTs using carbon nanorings, viewed as sidewall segments without the cap was also developed [126] but the researchers were unable to control the chirality of the as-grown CNT. An alternative technique was developed by other researchers using an organic chemistry approach to synthesize pure molecular seeds of C50H10 as an end-cap of a (5,5) chirality nanotube [130]. In this method, the researchers demonstrated chirality-controlled synthesis of SWCNTs through VPE elongation that was free of metals (Fig. 12a). Even though the grown nanotubes were well aligned and of high density, in Raman characterization, it was observed that the synthesized SWCNTs were not (5,5) chirality. It was also observed that the as-grown semiconducting nanotubes were of smaller diameters [130]. Around the same time, another method was demonstrated to synthesize single chirality SWCNTs with predetermined chirality by using an end-cap precursor and planar single-crystal metal surface [131]. In this method, the researcher’s custom synthesized a precursor (C96, H54) using organic chemistry approach to yield (6,6) nanotube seed through surface-catalyzed cyclodehydrogenation process (Fig. 12b). Although, Raman characterization using 532 nm laser identified that the synthesized SWCNTs had (6,6) chirality, some researchers argue that 532 nm is not in resonance with (6,6) nanotubes. In their study, they quoted that 532 nm was in resonance with (9,2) or (10,0) chirality nanotubes. Furthermore, few others observed that the splitting of G band is not consistent with initial studies in this area that demonstrated the G band of armchair metallic nanotubes as a single symmetric peak [132, 133]. The researchers have recommended further Raman characterization, STM studies to determine whether the as-grown SWCNTs are of (6,6) chirality. The use of organic chemistry techniques has the potential to be referenced in further development of chirality controlled SWCNT synthesis due to the possibility of large-scale synthesis with higher purity.
Most of the fabrication methods used to grow SWCNTs produce polydisperse CNTs of metallic, semi-metallic and semiconducting properties. This variation is based on the way the graphene sheet is wrapped, denoted by the indices (n, m) that define the chirality of the tube grown. Steps to control these variations are essential for various applications of SWCNTs as the presence of multiple conductivity types can hinder the device performance. Some of the earlier techniques involved the use of gas-phase etchants like methane plasma [134], water vapor [135], oxygen [136, 129, 137] and hydrogen [134], that would etch metallic particles during the synthesis due to their higher reactivity with the metallic nanotubes, thereby leaving the semiconducting nanotubes behind.
Using floating catalyst chemical vapor deposition (FCCVD) technique with oxygen as an etchant in selective removal of m-SWCNTs, ~ 90% yield containing s-SWCNTs with diameters 1.4–1.8 nm were obtained [137]. However, oxygen can combine with other carbon-based materials due to its strong oxidizing properties during the growth process. Controlling the concentration of oxygen during the growth process is a challenging task. As an alternative, water vapor can be used as an etchant in the CVD technique, as it has a much weaker oxidizing ability. A yield of ~ 97% was reported with this technique [138].
Recent studies have reported the importance of diameter dependence on the etching mechanisms. In one of the studies, m-SWCNTs were selectively etched using methane plasma, followed by annealing. At the end, s-SWCNTs are retained on the growth substrates which were stable at high temperatures [139]. By narrowing the diameter distribution to an optimal range of SWCNT diameter, most of the m-SWCNTs are etched within this range. In another technique, to control the diameter distribution, bimetallic solid alloy catalysts like Fe–W (Iron-tungsten) nanoclusters were used as catalyst precursors due to high-temperature stability of tungsten, which causes the nanoclusters to be stable during the CVD synthesis. Water vapor was used as an etchant during the growth process. A yield of ~ 95% was reported with this technique and the diameter of about 90% of the s-SWCNTs formed on the quartz substrate was reported to be in the range of 2–3.4 nm as shown in Fig. 13 [140]. A similar experiment using Fe nanoparticles as catalysts was performed where the overall yields showed broad distribution of the catalyst particle size due to mobility of Fe nanoparticles, which are usually in liquid state during high-temperature CVD growth [94].
Another technique to grow s-SWCNTs with narrow diameter distribution is using carbon-coated cobalt nanoparticle catalyst (termed as acorn-like catalyst) as shown in Fig. 14. The Co nanoparticle acts as active catalytic phase for SWCNT growth. Carbon coating on the outer end prevents aggregation of Co nanoparticles, a major problem faced by most growth methods that lead to formation of larger particles during SWCNT growth at high temperatures [141]. In this technique, the yield of s-SWCNTs grown was ~ 95% with a very narrow diameter distribution centered at 1.7 nm [138].
Controlling CNT Geometry
Diameter
Growth of SWCNTs with controllable diameters is regarded as one of the critical parameters in influencing its electrical, surface functionalization and thermal properties [1]. Properties such as band gap and chirality can be controlled by variations in the diameter of the SWCNTs formed. SWCNTs diameter control may be via their growth using floating catalyst method or from a substrate growth method with catalysts deposited on top or using template growth approach. Of the first two techniques, growth via floating catalyst method offers better control over the diameters of the tubes grown due to limited aggregation as catalysts are not restricted on a single plane of the substrate. Studies have shown diameter control in the range of ~ 1.2 to 2.1 nm using this method [126]. In one of the studies, diameter control was achieved by adding CO2 (which acts as an etching agent to etch tubes with small diameters) with the carbon source into the aerosol CVD reactor. The corresponding transmission electron microscope (TEM) image and the absorption vs. wavelength plot of SWCNTs grown with different CO2 concentrations is shown in Fig. 15 below. Increasing the concentration of CO2 leads to the shift in SWCNT diameters from 1.2 to 1.9 nm [142] as shown in Fig. 15c. Size and properties of the catalyst also play a significant role in the controlling the growth of SWCNTs and MWCNTs. Smaller particle size (a few nm) leads to the growth of SWCNTs, whereas MWCNTs are formed when the particle size is larger (tens of nm) [143]. For example, with Fe catalyst of average diameters of 9 and 13 nm, MWCNTs of average diameter 7 and 12 nm were produced [105].
Substrate growth method aims at minimizing particle aggregation by increasing catalyst spacing. For example, centrifuging the nanoparticles before deposition via CVD using ferritin catalyst particles leads to a diameter control in the range of. 1.9 to 2.4 nm [144]. Alternatively, by sandwiching Fe between Al2O3 in a sandwiched catalyst model, SWCNTs with diameters between 0.8 to 1.4 nm were synthesized [145]. However, SWCNTs grown using these techniques were entangled due to large catalyst spacing.
Another way of controlling the diameters of SWCNTs is by using a template-based growth approach [126, 146,147,148]. Use of carbon nanorings (cycloparaphenylenes), representing the shortest sidewall segment of armchair CNTs (Fig. 16) as growth templates and ethanol as a hydrocarbon source, SWCNTs with diameters in the range of 1.2–2.2 nm were grown. Different types of nanorings (based on number of benzene rings in the structure) were used as growth templates. The diameters of SWCNTs grown were similar to the diameter of the carbon nanorings used, thereby providing an avenue for diameter control of SWCNTs using organic chemistry approaches.
Several methods report the growth of MWCNTs with controlled diameters [149,150,151,152,153,154]. In one of the methods, aligned CNTs with diameters in the range of 20–400 nm and lengths between 0.1 and 50 μm were produced using the plasma-enhanced hot filament CVD method by tuning the catalyst size (Fig. 17a). Another method reported the importance of supply of carbon reactant and the growth temperature in the formation of large diameter nanotubes [105]. Here, the use of an iron nanocluster with diameter of 9 nm, ethylene as the carbon reactant and growth temperature of 900 °C, large diameter nanotubes with two or three walls were produced. Alternatively, arrays of SWCNTs with diameters of ~ 1.5 nm were obtained using lithographically patterned metallic nanoclusters (Fig. 17b).
Junctions
Modifications in the growth of CNTs leading to junction-like formations can create nanotube structures like the three-terminal Y-junction that could be used for novel electronic switching devices and transistors [155,156,157,158]. Y-junction nanotubes can be grown by CVD using anodic alumina templates with adjustable stem and branch templates [159, 160] as shown in Fig. 18a. Another method used Ti-doped Fe catalysts in the growth process to produce MWCNTs (~ 90%) branched in the form of a Y-shaped junction on quartz substrates (Fig. 18b) [161].
In addition to the above techniques, SWCNT junctions formed via crossing of different CNTs connected via irradiating the junction with electron beam, using scanning electron microscopy (SEM) have also been reported [162, 163]. Here, under the influence of electron beam, hydrocarbons used in the growth process are transformed into amorphous carbon which is then utilized to attach the nanotubes and form mechanical junctions (Fig. 19a, b). In another similar work, various carbon nanotube junctions (Y-, T-shaped) were formed by electron beam welding which induced structural defects in the nanotubes, leading to the joining of tubes by cross-linking of dangling bonds (Fig. 19c, d) [162].
Alternatively, two-terminal SWCNT junctions can be grown in a controlled manner using temperature modulation during the CVD process (Fig. 20) [141]. In this method, by altering the growth temperature, systematic variations in the diameter and chirality of the SWCNTs lead to the formation of SWCNT intramolecular junctions. These junctions were grown at desired locations by increasing the temperature of the substrate locally using infrared light during CVD. It was also observed that increasing the temperature led to a decrease in the diameter of the growing junctions and vice versa, with no change in the catalyst particle present at the growing tip [141].
Post-Growth Purification/Sorting of Single Tubes
Understanding CNT sorting methodologies is important as many of the advanced applications, such as FETs and nanoscale sensors, require monodispersed samples with little structural variation [164]. Before CNT sorting can take place, the tubes must be dispersed in a liquid medium (water or organic solvents). Unfortunately, there are certain constraints which may prevent separation in an aqueous dispersion. For example, CNTs have very strong Van der Waals interactions which restrict sorting [87]. There are several well-developed techniques currently being used for the post-growth purification or sorting of tubes. Some of these are discussed below.
One of the techniques, commonly referred to as the density gradient ultracentrifugation (DGU), has been shown to produce a high yield of pure SWCNTs, without much need for chemical treatment of the sample [165, 166]. DGU, which depends entirely on the buoyant density of the CNT, is an isopycnic separation process. The process is achieved by wrapping the SWCNT sample with a surfactant (Fig. 21) [166]. After the grown SWCNTs are mixed with the surfactant, the aqueous dispersion of surfactant-encapsulated tubes is added to the centrifuge tubes, which contains a pre-existing density gradient medium. A strong centrifugal force is then applied, and it causes the surfactant-wrapped SWCNTs to be separated by the movement of SWCNTs to regions of the density gradient medium which match the tubes’ buoyant densities (isopycnic points). The aqueous dispersions of the SWCNTs are produced by using either linear chain surfactants or bile salts. The density gradient medium is usually made of a salt (lithium chloride, cesium chloride, sodium chloride) solution in water. Nonlinear gradients are preferred because they are very sensitive and allow trapping of particles over the entire length of the centrifugal cell. The gradient density and its variation are important to the sorting process wherein, the gradient needs to be set up such that the distance between the tubes and their isopycnic points is minimal. As the density gradient medium responds to the centrifugal force, it leads to steeper gradient over time and hence redistribution of the density profile takes place during centrifugation [167]. After the centrifugation process, the sorted SWCNTS are removed layer by layer using the fractionation process (using piston, upward and downward fractionation methods), which involves extracting quantities of mixtures to different aliquots which vary in composition with respect to the density gradient of the original mixture. Uniform surfactant coverage is important or adsorbed surfactant molecules will begin to aggregate and form clusters along the tube sidewalls, thereby impeding effecting separation of the tubes. To separate metallic and semiconducting tubes, a co-surfactants mixture is used for the ultracentrifugation process. After the semiconducting tubes have been separated, chirality enrichment of tubes is carried out to generate samples that are rich in a certain chirality of tubes, and the resulting semiconducting-SWCNTs-enriched fraction is passed through a dialysis membrane to remove the surfactants from the SWCNT sidewalls [168]. Finally, the tubes are characterized using various optical spectroscopy methods.
Another separation technique, referred to as the ion-exchange chromatography (IEX), is based on the ion-exchange processes occurring between a mobile phase and stationary ion-exchange groups (which are bonded to the support material). The IEX separation method is carried out on single-stranded-DNA-wrapped (ssDNA) SWCNTs, which have different electrostatic interactions with an ion exchange column [169, 170]. By selecting the desired sequence from the vast ssDNA library, purification of the specific (n, m) species was possible. With certain ssDNA sequences greatly improving separations between metallic and semiconducting CNTs as well as between semiconducting CNTs of different diameters and electronic band gaps [171]. The IEX process begins by wrapping ssDNA around individual SWCNTs, to form DNA/CNT hybrids. Some of the DNA/CNT hybrids in aqueous dispersions are electrostatically bound to the positively charged anion-exchange resin (stationary phase). As the mobile phase is passed over the hybrid-resin system, and its ionic strength increases, hybrids with the lowest effective charge density elute within the shortest IEX times. Because the hybrids are found in both the stationary and mobile phases, the separation is based on differences in this distribution. There is less electrostatic attraction between metallic hybrids and the IEX resin than between semiconducting hybrids and the IEX resin, thus in a mixture of metallic and semiconducting CNTs of the same diameter, the metallic hybrid will elute from the column first. This method of DNA-wrapped CNTs produced many single-chirality semiconducting CNTs. Figure 22a shows the optical absorption spectra of 12 purified semiconducting SWCNTs along with their structure. This method could also be used for purification of armchair metallic tubes [133, 169]. An alternative approach to sort metallic and semiconducting CNTs is using anion-exchange chromatography technique. Here, single-stranded DNA form stable complexes with CNTs and can effectively disperse them in water. Here, the chosen DNA sequence self-assembles into an ordered structure around an individual nanotube, helping in nanotube formation (Fig. 22b).
Gel chromatography, particularly, agarose gel chromatography is a method of separating semiconducting CNTs from metallic CNTs in an mass-spectroscopy mixture using hydrogels [172, 173]. Agarose gel beads are used for mass-spectroscopy separation, owing to their simplicity, affordability, short process time of about 20 min and scalability. The mechanism for gel chromatography follows a few simple steps. First, the SWCNT mixture, containing both metallic and semiconducting CNTs, would be dispersed in an aqueous surfactant solution, such as sodium dodecyl sulfate (SDS). The wrapping and encapsulation of the SDS surfactant molecules around SWCNTs plays a crucial role in the separation mechanism. The interaction between SDS molecules and SWCNTs via ion-dipole forces depends on the pH condition and concentration of SDS molecules. Due to the electrostatic properties of SWCNTs [174], SDS molecules form different types of micellar structures around semiconducting and metallic SWCNTs [172, 175]. On semiconducting CNTs, randomly oriented, flat micellar structures are formed, while for the metallic CNTs, cylindrical micellar structures are formed. This is mainly due to difference in ion-dipole forces between metallic and semiconducting CNTs during their adsorption on agarose gel. These disparate encapsulation mechanisms form the basis of the separation process. After the SWCNT dispersions are formed, they are ultra-centrifuged to remove SWCNT bundles and other impurities, and the SWCNT-surfactant solution is pipetted to be used in the separation process. Next, a separating column is filled with agarose micro-beads suspended in ethanol, after which the column is washed and equilibrated using the surfactant aqueous solution. The agarose-SWCNTs mixture, which is to be separated, is then poured into the column, and the SDS solution is added. This causes a displacement of the SWCNT dispersion along the column. A portion of the SWCNTs (the semiconducting CNTs) are trapped at the top layer of the agarose beads, while the metallic CNTs move to the bottom of column. This movement is related to the encapsulation of the tubes. Because semiconducting SWCNTs are encapsulated by flat randomly oriented SDS micelles, and have less surfactant coverage, there will be an ineffective shielding between the semiconducting SWCNTs and the agarose gel, and thus, a stronger affinity of the semiconducting SWCNTs to the gel. However, the metallic SWCNT walls are surrounded by an ordered high-density cylindrical micellar structure, which causes a steric hindrance between the SWCNTs and the agarose gel. Therefore, the metallic tubes have less affinity to the agarose gel. A schematic of SWCNTs separation based on the chirality of the tubes is shown in Fig. 22c, d [176].
Another technique to separate metal and semiconductor nanotubes is using the technique of dielectrophoresis (DEP). When a particle is placed in an electric field, a lateral force, also known as a dielectric force acts on it [177]. This force can be used to manipulate nanoparticles or cause them to move, and the resulting movement of particles is termed dielectrophoresis [178]. The operating principle of the alternating current (AC) DEP process is based on the fact that metallic and semiconducting CNTs have different dielectric constants. The setup consists of a fabricated microelectrode, fluidic chamber and the SWCNT solution. The DEP force is generated by applying a non-uniform electric field to the setup. Due to the applied electric field, a dipole moment is induced on the SWCNT mixture, and the tubes will move towards the maxima or minima of the electric field depending on their polarity. Under the action of an AC electric field, CNTs in solution will move to the electrodes depending on their surface charge [179,180,181]. The electrodes are typically fabricated using e-beam lithography, which are then attached to a function generator. When an AC electric field originating from the function generator operating at 20 V peak-to-peak voltage and a frequency of 10 MHz is applied, a suspension of ~ 10 μL of SWCNTs is deposited. The metallic nanotubes will attach themselves to the electrodes, while the semiconducting tubes will remain in the suspension (Fig. 23) [182]. This is due to the divergent responses of the different types of CNTs to the electric field. In this technique, direct current (DC) electric field is not usually used as it leads to aggregation of CNTs near one of the electrodes [179]. The applied electric field and deposition time are the crucial parameters which control the CNT deposition yield.
Gel electrophoresis was developed as an improvement to the AC dielectrophoresis method. This process makes use of the same mechanism as AC electrophoresis but uses agarose gel as a medium. SWCNTs dispersed in an aqueous SDS surfactant are used to fill a gel column and subjected to an electric field. This causes a movement of the m-SWCNTs through the gel medium to the anode while the s-SWCNTs are adsorbed to the gel [177, 178].
Sorting of CNTs can also be done using solution-based conjugated polymers which can be used for selecting pure semiconducting SWCNTs from CNT samples. Here, semiconducting CNTs are wrapped with conjugated polymers, and this technique is considered helpful for selective and large-scale sorting of CNTs [183]. In this method, the SWCNT-polymer mixture is sonicated in an organic solvent for half an hour in order to disperse the SWCNTs. Next, the polymer-wrapped SWCNT solution is centrifuged for about an hour, which results in the sedimentation of m-SWCNTs. Finally, the s-SWCNT supernatant/liquid, which is found lying above the m-SWCNT sediments, is collected for use [183].
In another technique, a gas-phase plasma hydro carbonation reaction is used to selectively etch and gasify metallic nanotubes, retaining the semiconducting nanotubes in near-pristine form [139]. In this method, an array of 98 devices each consisting of ~ 0–3 as-grown SWCNTs grown using CVD were fabricated on an oxide-coated Si substrate. Each SWCNT was of ~ 1–2.8 nm in diameter. These arrays consisted of 55% semiconducting tubes which were non-depletable by the sweeping gate voltage, and about 45% metallic tubes which were depletable with on/off conductance ratio of ≥ 103. These arrays were exposed to methane plasma at 400 °C and then annealed at 600 °C in a quartz tube furnace. Post this, it was observed that the metallic CNTs were selectively removed and the semiconducting tubes were left behind in a greater proportion of about 93%.
Assembly/Placement/Integration of Multiple CNTs
Integrating multiple CNTs is essential for the realization of large-scale device applications. This has proved challenging due to the need for precise control and positioning of the fabricated CNTs with respect to other device elements. In this section, we focus on some of the existing techniques that are used in the process of batch level control, fabrication of multiple CNTs and their subsequent integration onto the substrates.
Batch Level Control
Catalyst Patterning
During CVD, a catalyst is often dispersed on the substrate from a solution containing a suspension of the nanoparticles. This is done by spin coating the substrate or by dipping the substrate into the catalyst solution. Alternatively, catalysts can also be deposited on the substrates by evaporation to create thin films. In order to position the catalysts at specific locations, different lithographic techniques like photolithography and microprinting have been reported.
Photolithography is used to pattern the catalyst which leads to growth of CNT thin films after lift-off. In one of the methods, controlled growth of CNTs with diameters of 0.5–1.5 nm was reported using Fe salt as catalyst. In this work, photolithography produced liquid catalyst islands on polymethyl methacrylate (PMMA) and alumina substrates. However, most of the CNTs grown were randomly oriented [184, 185]. Self-assembled masks can also be used to pattern catalysts in solution in order to control the positioning and alignment of nanotubes [186]. Another work reported the controlled growth of CNT thin films in certain regions by catalyst particle patterning using self-assembled monolayers. Here, a thick silicon substrate was thermally oxidized and positive photoresist mesas where CNT thin films were formed were patterned [187]. In a recent work, the growth of SWCNTs with diameters in the range of 0.7 nm to 2.6 nm using Prussian blue analog (PBA)-based bimetallic catalysts was reported [188]. Control on the overall catalyst size and properties was possible by synthesising PBA nanoparticles with narrow size distribution. Silicon wafers coated with an oxide layer were used as substrates. On these, a self-assembled monolayer of silane molecules (having a pyridine group at the ends) was deposited in order for the bond formation with the PBA nanoparticles to occur. Catalyst precursor reduction and the SWCNT growth were done via CVD with CH4 (Fig. 24).
Nano-imprint lithography (NIL) is another technique for patterning the catalyst [189]. This technique can be used to produce CNTs (in the form of both individual tubes and arrays or forests) with sufficient degree of control over diameters, length and quality [190, 191]. NIL uses silicon molds/stamps with different patterns of nanoscale features to imprint a desired pattern onto a polymer-based thermal resist. After this, required pressure and ultraviolet (UV) light are applied to solidify the polymer resist and form desired circuit patterns. In some cases, temperature can also be applied to the photoresist instead of UV light. Later, the stamp is removed from the resist which leaves behind an imprint of the desired patterns on the substrate. The residual layer of polymer is removed by plasma etching, thereby exposing the substrate onto which the catalyst is deposited. This substrate is loaded into CVD to grow patterns of CNTs. An example of this step-by-step procedure and the corresponding scanning electron microscope (SEM) images of CNTs grown using NIL is shown in Fig. 25 [192, 193].
New techniques using nanolithography like nanowriting with nanopipettes [194] and dip-pens [195] help in the growth of CNTs at predetermined locations. For example, in the dip-pen method, the tip of an atomic force microscope (AFM) is usually dipped in an ‘ink’ that can subsequently be transferred to a substrate with nanometer-scale precision. Similarly, nanowriting provides direct and precise control over surface patterning without requiring complex lithographic processing [196].
Controlled production of large-area SWCNT networks can also be done using precise nanometer-scale catalyst patterning resulting in desired alignment of individual SWCNTs on silicon [197]. In this method, the catalysts act as a breadboard that connects the nanotubes with desired alignments. Here, a colloidal mask was used to pattern catalyst nanoparticles using polystyrene spheres that were deposited from liquid suspension and allowed to self-assemble during drying into hexagonal close-packed monolayer regions as shown in Fig. 26.
Additionally, catalyst patterning can also be used to control the growth orientation of CNTs during CVD by patterning the catalyst layer on slanted surfaces etched using potassium hydroxide (KOH) as shown in Fig. 27 [198]. In this technique, the catalyst is patterned fully or partially on slanted trenches fabricated via KOH etching. After this, the patterning of a catalyst layer (of 1 nm Fe and 10 nm Al2O3) is carried on the sidewalls using lift-off and e-beam evaporation. Then, CVD is used to grow CNTs with the following conditions; growth was carried out at 775 °C for ~ 5 or 15 min).
Electric Field, Gas Flow and Substrate-Assisted Growth
Controlled synthesis of CNTs can be achieved by growing them on the SiO2 /Si substrates in electric fields established across patterned metal electrodes [199]. In this technique, Si wafers were used with thermally grown SiO2 as substrates. Molybdenum (Mo) metal electrodes with a gap of 10 mm were used to establish electric fields on the substrates. Then, the desired catalyst was patterned on top of the two opposing Mo electrodes leading to the growth of aligned SWCNTs across the gap between the electrodes in the direction of the applied electric field. Figure 28 [199] shows the AFM images of randomly grown nanotubes in the absence of an electric field and aligned nanotubes grown in the presence of an electric field.
Another method of controlling the growth of CNTs is based on rapid heating (900 °C for 10 min) of catalyst nanoparticles (Fe/Mo) in the presence of feeding gas (CO/H2) [200,201,202]. SWCNTs were grown parallel to the direction of feeding gas flow. This work reported directional control of the CNTs grown by positioning the substrate based on the gas flow direction. The location and length of SWCNTs was controlled by using photolithography to deposit the catalysts. This method produced ultra-long, well-aligned and well-isolated SWCNTs with length of few mm (Fig. 29) in contrast to an earlier work that reported that long SWCNTs (in the range of mm) either bend or form loops [203]. Here, the growth of long and straight SWCNTs was attributed to the above described growth process also termed as a kite-based growth mechanism [201].
Large scale, highly aligned SWCNTs arrays can also be grown by interactions between SWCNTs and the substrate [204,205,206,207] using atomic arrangement-programmed growth. Highly aligned SWCNTs could also be grown using Y-cut single-crystal quartz or ST-cut quartz substrates using CVD of methane at 900 °C and Fe catalyst. As shown in Fig. 29c, SWCNTs with diameters of 1 ± 0.5 nm were grown on quartz using this technique. In this method, SWCNTs were synthesized using CVD of methane at 900 °C with Fe clusters that were dispersed on the sapphire substrates. Alternatively, use of a-plane and r-plane sapphire (Al2O3) substrates led to guided growth along specific lattice directions due to the attractive interactions between nanotubes and Al atoms that are oriented in specific crystalline directions on the substrates (Fig. 29d).
CNT Forest Growth
CNT forests (or CNT arrays) are arrays of vertically aligned CNTs that offer applications in the field of sensors [208], gecko tapes [209], strong fibers [210] and electrical interconnects due to their ability to carry high current densities of ~ 108 A cm−1 [211, 212]. Various techniques such as use of plasma CVD, nanopatterning and flying carpets have been proposed as means of growing CNT forests [210, 213, 214]. Of these, CVD is regarded as one of the most efficient techniques to grow vertically aligned CNTs. Precise diameter control of CNT forests using pre-growth conditioning and catalyst engineering is one of the crucial parameters that influences its use in various applications [215,216,217]. In addition, control of number of layers and length of the tubes grown is also essential [218].
Growth of aligned MWCNT forests with diameters of ~ 8–15 nm was achieved using CVD in a quartz tube. Here, a Si wafer was used as a substrate, onto which a 5-nm-thick film of Fe (acting as a catalyst) was deposited using e-beam evaporation [219]. An alternate method for the fabrication of a closely packed MWCNT forest was reported using a multi-step growth method based on plasma-induced CVD technique [220]. The growth mechanism involves the following steps. First, very high-density plasma-induced catalytic nanoparticles were formed from a pre-deposited catalytic thin film. It was observed that these catalytic nanoparticles tend to aggregate at higher temperatures. In order to avoid this, the CNT nucleation process (immobilization procedure of catalytic nanoparticles) was performed and showed minimal aggregation of nanoparticles covered with graphitic carbon film. Finally, closely packed MWCNT forests were grown at a temperature of 450 °C (Fig. 30) [221, 223].
The direction of alignment of CNTs with respect to the substrate plays a crucial role in controlling the properties of CNTs grown. CNTs aligned vertically (i.e. perpendicular) to the substrate can be produced using porous silicon substrates with a catalyst patterned by electron-beam evaporation through shadow masks to produce MWCNT blocks. Another technique to produce these CNTs is using water-assisted CVD that produced SWCNT arrays in the order of few millimeters [135]. Here, large-scale production of dense CNT forests was reported to be possible with the help of CVD synthesis where the performance and lifetime of the catalysts was enhanced with the help of water. SWCNTs in the form of well-ordered pillars with a height of ~ 1 mm were grown from lithographically patterned catalyst islands as shown in Fig. 31 below. Alternatively, large-scale production of vertically aligned SWCNT forests is also possible using the oxygen-assisted CVD method. It was reported that the hydrogen species present during hydrocarbon CVD growth method may cause difficulties in the formation of new SWCNTs and can also potentially etch preformed SWCNTs. The introduction of oxygen during the growth process provides great control over the carbon and hydrogen ratio which is responsible for the growth of vertically aligned SWCNTs [223]. More recently, it was also shown that SWCNT forests could be grown using thermal CVD without a rectated etchant gas [224].
Another technique involves the fabrication of the CNTs within the pores or channels of a nanoporous template [160, 225, 226]. The commonly used templates are track-etch membranes, porous alumina (AAO) templates as well as various other nanoporous structures. Template-based synthesis allows the preparation of nanomaterials with a desired shape. A template is basically a structure in which the CNT networks form. Once the template is removed, it exposes a filled cavity with features similar to those of the template. After deposition, the nanotubes may be allowed to remain inside the pores of the templates, or they can be collected as a group of free nanoparticles. The template-based deposition process commonly makes use of CVD techniques, in which hydrocarbon precursors like pyrene and ethylene are exposed to elevated temperatures inside alumina templates. As the thermal deposition of the gas occurs over the entire surface of the pores, this method offers considerable control over the length and diameter of the tubes. One example of the growth of highly ordered arrays of parallel CNTs inside a hexagonally close-packed nanochannel alumina template is described below. At first, the anodization of high purity alumina was carried out, and led to the creation of a nanochannel alumina template made up of hexagonal array of channels with a diameter of 32 nm and length of 6 μm. Next, a small amount of catalyst (Co) was deposited electrochemically into the bottom of the template channels. By heating these templates at 600 °C for 4–5 h in a tube furnace in the presence of CO, then in a mixture of acetylene in nitrogen at 650 °C for 2 h, growth of highly ordered array of nanotubes was observed (Fig. 32) [160, 227]. Periodic array of nanotubes with diameters ranging from 10 nm to several hundred nm were grown by pyrolysis of acetylene on Co at a temperature of 650 °C.
Another method in the growth of SWCNT forests, involves the introduction of gas shower system to deliver water vapor and carbon source gas from the top of the forests, rather than traditional way of delivering from the side. This method enables parallel flow of water vapor and carbon source gas to the CNTs within the forest. This technique enables mass production of CNT forests with increased growth yield, height, carbon efficiency and scalability for large area growth [214, 228].
Macrostructure Fabrication
Fabrication and assembly of CNTs on a macroscale is of utmost importance in order to enhance its practical applications [179]. A commonly reported technique is using spin coating. This process of fabricating CNT films involves depositing droplets of CNT-based suspensions at the center of a substrate and then spinning the substrate to a very high velocity such that the CNT dispersion spreads out on the surface of the substrate, forming a thin film (Fig. 33a) [229, 230]. This process is due to the centrifugal force on the CNT dispersion. The thickness of the film depends on the viscosity of the dispersion, angular speed, spin time and the concentration of CNTs. Before the CNT dispersion is formed, it is important to overcome the Van der Waals forces between the tubes, else they will tend to aggregate and form clumps on the film. Amphiphilic surfactants are usually added to enhance the dispersibility of the tubes; conventional surfactant will not suffice because there is a strong charge repulsion between the CNT complexes and the surfactant, which prohibits the deposition of CNTs onto the substrate. Additionally, high-power ultra-sonication or strong-acid treatment is usually performed on the tubes. After the CNT film is deposited, the surfactant is usually either washed off or vaporized from the surface of the substrate. Spin coating is not applicable for large substrates because they cannot be spun at a sufficiently high rate to form an even layer. Additionally, the process lacks material efficiency as a lot of the material is flung off during spinning [229]. Alternatively, electrophoresis process can also be used for the film deposition of CNTs [231]. Some of the other relevant techniques include using composites [232], foams [233], yarns [210] and aerogels [234] as discussed below.
CNT Composites
Due to the various properties that CNT’s exhibit, especially being superior in stiffness and strength, they can be widely used in structural applications. Furthermore, researchers are showing increased interest in tapping CNT’s properties by fabricating them into a polymer matrix. Some of the commonly used CNT-based polymer composites are made up of polystyrene, ultra-high molecular weight polyethylene (UHMWPE), PMMA, epoxy and phenolic resin [62, 235,236,237]. Various techniques have been proposed for fabricating CNT-polymer composites based on the material combinations used. Some of the common methods like solution casting, melt mixing and in-situ polymerization are discussed below.
Solution casting, also referred as solvent casting, facilitates CNT dispersion, where CNTs are suspended in the desirable polymer solution via magnetic stirring or sonication (energetic agitation process). The solvent is then allowed to evaporate to produce CNT-polymer composites. Polymers such as polyvinyl alcohol (PVA) [238], PMMA [239] and epoxy [236] have been used in this method. One such manufacturing technique is shown in Fig. 33. Here, PVA/CNT composite fibers of ~ 50 μm diameter were synthesized using the following steps. First, CNTs were dispersed in ethanol, then a PVA-coated polyester strip was dipped in a solution containing the CNT mixture. Then, the CNT-coated PVA on the polyethylene terephthalate (PET) strip were delaminated. Finally, this delaminated layer was stretched and twisted to form a composite fiber (Fig. 33a). Studies involving different solutions and methods have demonstrated that the selection of solvent for nanotube dispersion had an influence on the properties of synthesized nanocomposites and the type of solvent is dependent on the solubility of polymer in it [240]. A major shortcoming of this method is that the nanotubes may agglomerate if the solvent evaporation process is slow. This may be mitigated by increasing the rate of evaporation [241]. This leads to inhomogeneous distribution of CNT’s in the polymer matrix [242].
Another commonly used method for the fabrication of CNT-polymer nanocomposites is called melt mixing. It is mostly used for manufacturing of thermoplastics and thermistors. Thermoplastic polymers melt/soften when heated to high temperatures thus making them less viscous. This causes the substrate to be less viscous and the need for high shear forces to disrupt the nanotubes bundle. In this method, composites of various polymers (such as polystyrene and polypropylene) are formed with CNTs. To start with, the selected polymers are mixed with nanotubes in a high sheer mixer. Post this, composite films are formed using compression molding [6]. Further studies in this area has enabled different techniques such as extrusion, compression molding, injection molding, etc. for fabricating samples of various shapes [6, 243, 244].
Recently, melt-mixing method was used in the manufacturing of positive temperature coefficient (PTC) thermistors using CNTs as conductive fillers in high-density polyethylene (HDPE) composites. Traditional PTCs manufactured using carbon black (CB) filled high-density polyethylene composites suffer from disadvantages like low thermal stability and poor processability. Use of CNTs in the manufacturing process can help in overcoming these challenges as the CNT-based thermistors showed ~ 129% increase in hold current and hold voltage, in comparison with the CB-filled composites [245]. These CNT/HDPE microstructure composites were prepared by melt-mixing, hot-pressing and packaging methods as shown in Fig. 34a. CNT/HDPE composites showed a decrease in electrical resistivity with an increase in the CNT loading. Figure 34b shows a comparison of current vs time plot obtained for CNT/HDPE and CB/HDPE thermistors.
CNTs can also be fabricated with monomers or polymers of higher molecular weight using in-situ polymerization. In general, this method can be used in the fabrication of almost any polymer composite with CNT to polymer matrix that is either covalently or non-covalently bounded [246, 247]. In addition, this method makes the grafting of larger polymer molecules to the walls of CNT possible. This enables the fabrication using insoluble and thermally unstable polymers that cannot be achieved by solution or melt processing. A stronger interaction of CNTs with polymers during the growth stage due to π-bonding was observed in this technique [248]. One such schematic of fabrication of CNTs using in-situ polymerization is shown below in Fig. 35 [249].
Many other lesser known methods to fabricate nanocomposites have also been proposed such as twin screw pulverization [250], latex fabrication [251], coagulation spinning [252] and electrophoretic deposition [253].
Foams, Yarns and Fibers
Three-dimensional porous networks made of polymers and CNTs have a great potential to be used in various applications like energy storage [254] and sensing [255]. Here, CNTs are used as modifiers into structures made of different porous materials like carbonaceous aerogels, foams and sponges [219, 234, 256]. Fabrication of CNT foams and aerogels can be done using several techniques like c-CVD, phase separations, polymerization reactions, etc. Creation of CNT foams and aerogels can be done using a bottom-up method consisting of phase separations induced by thermal phase transition. Here, a three-dimensional (3D) network of CNTs is initially formed in a solution, post which the liquid part is removed without disturbing this network. This technique is commonly referred as freezing as it involves a solid-liquid phase separation process. However, it was reported that CNTs grown using the various freeze-drying techniques lead to agglomerations [257].
Another technique of CNT aerogel formation is using a gas-liquid phase separation process, commonly referred to as foaming as shown in Fig. 36 [258]. Fabrication of CNT foams with controlled pore structures using this foaming process can be done using PVA, polystyrene, polyurethane, etc. [259, 260] An alternate route to the fabrication of CNT foams is using CVD, wherein, by controlling the growth parameters like type of catalyst and source of carbon, vertically aligned CNT array foams could be formed [233, 260]. Recently, aligned CNT foam structures of desired size were fabricated by stacking sheets of CNTs and infiltrating the stacked sheet assembly with pyrolytic carbon (PyC) [233]. Here, vertically aligned MWCNTs were grown using CVD technique with FeCl2 as catalyst and acetylene as the carbon precursor. These aligned CNTs were drawn from arrays and collected around two rotating parallel glass rods in order to have less compacted macro-porous structures. The CNT foams were then coated with 20 to 100 cycles of alumina buffer layers (that pins the catalyst particles on the surface of nanotubes) to help in the formation of secondary CNTs leading to creation of junctions, or branched CNT networks [260, 261]. In this method, prior to CVD, a buffer layer made of Al2O3 is deposited onto the porous structure to promote secondary CNT growth (in the form of straight CNTs or coiled-CNTs) at the surface of the primary nanotubes and within the pores of the CNT foams [261].
MWCNTs shaped into yarns have potential to be used in multifunctional applications like artificial muscles and actuators, in electronic textiles and as fiber-based supercapacitors [219]. Electromechanical actuators formed using sheets of SWCNTs (as electrolyte-filled electrodes of a super capacitor) are reported to have shown higher stresses than natural muscle. Like natural muscles, the macroscopic actuators are assemblies of billions of individual nanoscale actuators and are shown to have a great potential in various applications [39, 262, 263]. In addition, by twisting CNTs from a MWCNT forest, CNT yarns could be formed [219, 264]. Here, MWCNTs with a diameter of ~ 10 nm were drawn from a MWCNT forests (grown using CVD by using Fe catalyst) and twisted with a motor running a variable speed of ~ 2000 rpm [219]. This twisting causes the MWCNTs to form small individual bundles consisting of few CNTs. Further, by allowing the twisted yarns to relax (untwist in an opposite twist direction), knitted and knotted yarns were formed (Fig. 37a–c) [265,266,267]. Alternatively, MWCNT yarns could be synthesized from aerogels during CVD [268]. MWCNTs can also be drawn into sheets from MWCNT forests synthesized using CVD with ~ 3 nm iron film as a catalyst and acetylene or ethylene as carbon source [269]. These sheets were formed as a highly anisotropic electronically conducting aerogels that could be drawn into sheets with ~ 50 nm thickness as shown in Fig. 37d [270].
Recently, electrically conducting 3D fabrics made from hybrid Spandex (SPX)–MWCNT yarns showed excellent stretchable properties with a potential to be used as artificial muscles (Fig. 38). They were fabricated in a knitting machine into which a CNT aerogel sheet drawn from CNT forest, wrapped around continuous supply of SPX filament was fed. These fabrics exhibited breaking strains of 600% to 900%, tensile strengths in the range 75 to 86 MPa and an approximate resistance of 3.0 kΩ m−1 [271]. They offer unique advantages such as large tensile actuation, high repeatability, scalability and stretchability due to which they can be used in various applications like medical sensors/devices and smart clothing.
Alignment/Placement on Substrates
Most methods of CNT mass production result in randomly oriented CNT bundles. The placement and alignment of the tubes can either be done while they are being grown or after they have been grown. In the former, the CNTs are grown in a given direction and position within the substrate or normal to it, while in the post-growth method, the tubes are first isolated in a dispersion and then the dispersed CNTs are aligned and selectively positioned in a certain direction by applying external forces. Various methods have been used for aligning and placement of CNTs on substrates, as discussed below.
Photolithography
Photolithography has been successfully used to prepattern either catalysts or substrates for site-selective growth of CNTs. In such a case, the photolithography setup consists of a substrate (glass), a patterned resist and a photomask. The process involves the following steps; first, direct photolithographic patterning is performed on the metal-containing photoresist. Next, metal oxides are heated and then reduced by hydrogenation to patterned metal nanoparticles, which act as catalysts from which aligned CNTs are grown, via the hydrocarbon pyrolysis of FePc (Fig. 39a, b) [272]. Alternatively, catalyst patterning using photolithography can be done by creating a template with desired patterns of photoresist, followed by molding of PET stamps which are used in transfer printing of CNTs. However, this technique suffers from certain limitations which include not having the necessary resolution to grow nanometer-scale patterns. In addition, growth of CNTs may be hindered/affected due to contamination that may be introduced through these masks [195].
Transfer Printing
Currently, most nanoelectronics devices are being made on flat, rigid, smooth surfaces. This poses a problem because future nanoelectronics applications will require for nanomaterials to be placed on flexible substrates, such as plastic, or nonplanar materials. Due to this, methods such as transfer printing, which allow for the fabrication of a device on a conventional substrate and then transfer-printing of the entire working device onto target substrates, are being developed [273, 274]. This precludes the need for performing harsh synthesis and fabrication methods on the target substrate. The mechanism for transfer printing CNTs is as follows; first, the tubes are stabilized by mixing them with surfactant molecules, next the surfactant-stabilized CNTs are deposited on a variety of substrates from the solution. The most common process for the deposition of the tubes with wide area coverage is based on controlled flocculation. The controlled flocculation approach uses a spinning mechanism, in which the suspension of tubes and a solvent (methanol) are applied at the same time, to a spinning substrate. The methanol or any other hydrophilic solvent displaces the surfactant from the nanotubes, by bonding to them thereby causing the tubes to precipitate from the solution, to the edges of the substrate where they are deposited on a high-resolution polydimethylsiloxane (PDMS) stamp. The tubes form thick films on the PDMS stamps, and the stamp can be pressed on the target substrate to transfer the tube patterns from the raised regions of the stamp (Fig. 39c) [273]. One problem with this technique is the requirement to pattern the stamps each time based on the design [275].
Template-Based Deposition
Patterning in thin film CNTFET channels can be achieved with an inexpensive solution-based self-assembled colloidal mask that leads to devices with large on/off ratios while maintaining carrier mobility and sub-threshold performance. By guiding SWCNT thin film formation, the colloidal mask approach allows an ordered nanoscale CNT network with more consistent and accessible channel surface area resulting in patterned thin film FET channels whose structure and properties can be tuned for different applications (such as sensors). In one of the template-based deposition techniques, the patterned SWCNT thin films were fabricated using colloidal lithography [241]. This method employed a liquid-based self-assembly of colloidal sphere monolayers as masks to create ordered nanoscale arrays and films. Here, heavily doped silicon wafers with ~ 100-nm-thick SiO2 layer was used as a substrate and patterning of Au/Ti source-drain electrodes with ~ 40 nm thickness and 1–3 μm spacing on the surface of wafer was carried using photolithography. SWCNT powder (1.2–1.5 nm diameter and 2–5 μm length) was dispersed in chloroform with SDS surfactant to form aqueous suspensions, which was mixed with an aqueous suspension of silica or polystyrene colloidal spheres to form patterned nanotube networks. The overall process flow for patterning the SWCNT thin films and the corresponding results are illustrated in Fig. 40a–c.
Another technique to control the placement, alignment and spacing of CNTs is achieved using DNA-origami structures [276,277,278]. Here, various geometrical shaped (L-, T-, Y-, rectangular, triangular, etc.) nanotube structures are formed on DNA-origami templates using self-assembly process (Fig. 41), where the CNTs were organized into several patterns, with control over the inter-tube angles. In one of the techniques, CNTs solubilized by wrapping with ssDNA reacted with the DNA origami constructs forming linear arrays of ssDNA that lead to immobilization of the CNTs onto the DNA origami scaffold. This was due to the strong π–π interaction existing between the bases of ssDNA and CNTs. SWCNTs with lengths ranging from ~ 92 ± 24 nm (termed as short SWCNTs) and ~ 314 ± 249 nm (termed as long SWCNTs) were obtained in this work [276].
Solution-Based Deposition of CNTs
Most solution-based alignment or deposition methods of CNTs require the formation of CNT films from CNT suspensions. As such, there’s a need to form uniform dispersions of CNTs in a solvent. A challenge that is commonly encountered in dispersing CNTs is overcoming the strong inter-tube interaction of CNTs, which is attributed to van der Waals forces. When CNTs are placed in a solvent, they usually bundle together. This attractive force of the CNTs is usually overcome by binding the CNT walls to surfactant molecules (surfactant wrapping) to form stable solutions of CNTs. As such, these van der Waals forces are a major consideration when using solution-based methods for aligning CNTs [230]. Some of the solution-based alignment techniques are discussed below.
Inkjet printing is a precise method of patterning, and therefore, post-printing steps are not needed. This technique is advantageous because it does not require the use of a prefabricated template, thereby allowing for rapid printing at a low cost [279, 280]. Additionally, it is valuable because many layers of ink can be printed on top of one another. The carbon nanotube ink is prepared following certain steps; first, sonication is used to disperse the CNTs within the liquid. After dispersing the CNTs, the ink is centrifuged several times to separate the well-dispersed CNTs from the bundles, which could clog the printer nozzle. Next the supernatant is collected and filtered severally to remove any remaining CNT bundles. After the ink has been successfully produced, it is loaded into an inkjet cartridge and ready to be used for printing on substrates like glass and polymers.
Consumer inkjet printers are of two types; continuous and drop-on-demand. The former supplies a continuous stream of ink droplets, which are charged once they leave the nozzle, and are then deflected by voltage plates, such that the applied voltage determines if the droplet will be deposited on the substrate, while the drop-on-demand printer functions in a different manner, in that, the printer only ejects ink when required [279]. Carbon nanotube inkjet printing has been successfully used to deposit MWCNTs and SWCNTs. It has also been used to fabricate transistors, sensors and electroluminescent devices. The process is a useful development in electronics because it allows direct printing of the CNTs to make a pattern or a circuit on a suitable substrate, thereby enabling us to control the transparency and resistance of the printed patterns (Fig. 42a) [281]. In order to produce uniform networks of CNTs by inkjet printing, the jetting conditions need to be properly tuned to generate correctly directed droplets. Another important consideration is the temperature of the substrate. The substrates need to be heated in order to reduce the drying time for the printed CNT solution. For manufacturing purposes, quick drying of the dropped ink is desirable. However, the temperature should not be too high as it would cause the droplet to evaporate once it is released from the nozzle. A constraint in using this process is the difficulty of dispersing nanomaterials within the ink as CNTs typically bundle together in a solvent, due to their attractive van der Waals forces. The bundling of tubes needs to be prevented as it could cause clogging of the inkjet nozzle [279].
Alternatively, spray-coating involves spraying CNTs dispersed in a suspension on a heated substrate such that every sprayed droplet undergoes pyrolytic decomposition when it reaches the hot substrate surface thereby forming a thin layer of CNTs film [282]. CNT films can be spray deposited on glass before being transferred to a flexible substrate or they could be directly sprayed onto the flexible substrate. Before the spraying of the CNTs can take place, the solution has to be prepared. First, CNTs in powdered form are dispersed into a solvent via sonication. The CNTs are usually either dispersed in an organic solvent or in a surfactant-based aqueous dispersion. Surfactant-based dispersion using SDS or carboxymethyl cellulose (CMC) is usually preferred because the surfactants can be rinsed off after the film is deposited, as these surfactants are soluble in water. The surfactant is first dissolved in water to form an aqueous solution, to which the CNTs are later added. This forms a surfactant based aqueous CNT solution. Sonication of the surfactant-based solution is then performed to evenly disperse the CNTs. Finally, the solution is centrifuged, and the supernatant is taken from the top to be used for deposition. Before spray deposition of the CNTs can occur, the substrate surface has to be treated and cleaned using solvents like acetone and isopropanol, followed by plasma cleaning. After treatment of the substrate, the colloidal suspension of CNTs is sprayed through an air atomizing spray gun, onto a heated substrate. The dispersing fluid (in this case, the surfactant) then evaporates due to the heating of the substrate to leave behind a uniform coating or layer of CNTs.
CNT films can also be produced using the Langmuir-Blodgett (LB) technique, in which a substrate is dipped in a solution containing well-dispersed CNTs, and then slowly pulled out either by horizontal lifting or by vertical dipping method as shown in Fig. 42b, c [283]. This technique produces a thin layer of CNTs aligned in the dipping direction on the substrate. The thickness of the CNT film is dependent on the concentration of CNTs in the solution, the pulling speed, and the number of dips. Generally, SWCNTs are dispersed in an amphiphilic polymer matrix, spread on a water surface [284]. This film is transferred to a substrate by dipping the substrate in it. The disadvantage of this method, as with most solution-based methods, is that the solution might require a solvent that is incompatible with some substrates, for example plastic.
Well-aligned, horizontal arrays of semiconducting nanotubes can also be created using nanoscale thermocapillary effects in thin-film organic coatings (Fig. 43a, b) [285]. In this method, metallic SWCNTs are selectively removed via thermal resist exposure and etching. SWCNTs, grown on quartz substrates comprise of both semiconducting and metallic nanotubes with diameters between 0.6 and 2 nm. By means of thermal evaporation, thin organic thermocapillary resist layer of a,a,a′-tris (4-hydroxyphenyl)-1-ethyl-4-isopropylbenzene is deposited on these SWCNT arrays. Post this, by etching metallic CNTs are removed from the arrays.
Alternatively, aligned CNTs were deposited on a HfO2 trench with a density of 109 cm−2 using self-assembly (Fig. 43c, d) [286]. This was done through the SDS-wrapped CNTs dispersed in water and the use of 4-(N-hydroxycarboxamido)-1-methylpyridinium iodide (NMPI) to form surface monolayer. This led to ion exchange between Na+ in SDS and I− in NMPI. By controlling the concentrations of SDS surfactant and dimensions of the trenches, placement of CNTs inside the trench was randomly varied. With trenches of dimensions, 200 nm and 500 nm fabrication of a billion nanotubes per square centimeter is predicted. For example, one preliminary successful functioning CNT computer circuitry was self-assembled using selective surface chemistry [287].
Emerging Applications and Challenges
Figure 44a gives an overall summary and comparison of the various CNT assembly techniques presented in this review. As seen throughout the preceding sections, CNTs have gained widespread interest for use in applications [1, 39, 52, 57, 65, 66, 276, 288]. Electronic devices, sensors, drug delivery, energy storage devices, crypto primitives and tissue engineering are just some of the potential areas where nanotubes can be employed (Fig. 44b).
CNTs are used in various commercial applications in the form of conductivity enhancement/control in plastics [289], in anti-static packaging and to enhance the strength of concrete, polymers, baseball bats, bicycles, etc. [62, 289]. In addition, use of CNTs for structural monitoring in aircraft structures is currently patented [290]. Successful use of CNTs in this application may greatly reduce the risk of an in-flight failure caused by structural degradation of aircraft.
CNTs are also finding use in biomedical applications such as imaging [291,292,293], tissue engineering as scaffolds for bone growth [294, 295] and scaffolds to guide neurite outgrowth [296] as shown in Fig. 45a–c. In addition, CNTs can also to be used in targeted drug delivery systems (Fig. 45d) [297, 298] due to their capabilities to interact with mammalian cells. Due to their ability to penetrate into cell membranes, CNTs can be used as carriers to deliver therapeutic agents into the cytoplasm of cells. CNTs that are gastrointestinally absorbed were lysosomotropic and could enter into the cells for targeted drug delivery.
As mentioned previously, a major class of applications of CNTs is in electronic devices like FETs [46, 48, 299] and to build integrated circuits (ICs) and flexible electronics [300, 301]. Some of the other applications include their use in batteries, where a CNT film was used as the current collector for a lithium ion battery [302], in transparent conductive films that can be used in flat panel displays such as laptops and cameras [57, 303], hydrogen storage to be used as fuel source [304], as interconnects [305, 306] that can potentially offer advantages over copper (due to their high thermal stability and large current carrying capacity), in non-volatile random access memory for molecular computing [307] and in thin-film solar cells made up of a semi-transparent thin film of nanotubes on a n-type crystalline silicon substrate, wherein CNTs films are used as photogeneration sites and are also used for enhancing conductivity (Fig. 46a, b) [308].
Due to their unique thermal and mechanical properties, CNTs have also found applications as nano additives in heat conductive materials made of CNT-based lubricating oils, nanoliquids, etc. [309] These additives can be used for heat dissipation in electronic devices like LEDs and computer processors [309,310,311]. The high thermal conductivity of CNTs also enables their use as thermally conductive composites that could potentially replace metallic parts in devices such as electric motors and generators [14, 312, 313].
In addition, CNTs have also been tested to create an unclonable electronic random structure to create cryptographic keys that can be a used to provide significantly higher level of security as compared to the conventional binary-bit architecture with the same key size [314, 315]. A schematic of generation of random bits based on two-dimensional (2D) carbon nanotube arrays is shown in (Fig. 46c). In this method, well-aligned CNTs are deposited on a HfO2 trench, ~ 7 nm high using self-assembly. This was done through the SDS-wrapped CNTs dispersed in water and the use of NMPI to form a surface monolayer, which led to ion exchange between Na+ in SDS and I− in NMPI. By controlling the concentrations of SDS surfactant and dimensions of the trenches, placement of CNTs inside the trench was randomly varied. Further, CNT thin films, also known as CNT mats, have shown potential to be used in radio-frequency signal transmission [316]. A combination of most of the above applications includes the use of CNTs in wearable electronics consisting of many memory units, capacitors, transistors and logic circuits, etc. (Fig. 46d) [317]. In one of the recent examples, stretchable and ultrathin wearable array of electronic devices with a dimension of ~ 3 μm showed a possibility to be integrated on the human skin. Techniques such as spin coating, thermal evaporation and photolithography were used to fabricate these devices based on the required application.
Use of aligned/organized CNTs in the form of yarns, forests and sheets can help in further development of CNTs for large-scale industrial applications. Some of the emerging applications of CNTs include their use as multi-functional coating materials, which in turn can be used as an alternative to environmentally hazardous paints containing biocides [288]. CNTs have also proven useful in anticorrosion coatings in metals (showing enhanced strength and coating stiffness) [318], and in transparent electronics like flexible displays. Due to their ability to be manufactured as metallic, semi-conducting or wide-band gap CNTs, they can also be used in manufacturing new generation electronic components and devices like batteries, supercapacitors, transistors, logic circuits, memristors, neuromorphic computing, sensors for optics, gas, pressure, glucose, tumor detection, electronic textiles, artificial muscles and electro-thermal actuators, etc. [1, 219, 297, 307, 319, 320]. CNTs have a potential to be used in other applications in the form of wires in nanoscale very-large-scale integrated (VLSI) circuits [306], to fabricate flexible and foldable sheets [321], fibers via wet spinning [264, 322], in energy and water treatment [323].
Despite their numerous advantages and potential applications, several outstanding issues related to CNTs must still be addressed in order for their potential to be fully realized in the future (cf. Fig. 44a): For example, low mechanical strength and thermal conductivity of the typical as-grown CNT material has to be studied and improved. In addition, during the growth of long nanotubes tubes with closed ends are also formed due to the presence of pentagonal and heptagonal defects in the graphene lattice. This makes it difficult for their use in many applications where access to open-ended tubes is needed, e.g. to functionalize and/or contact the tube ends. Also, controlling chirality of the CNTs grown, which critically influences the electrical properties of the nanotubes is still considered a major challenge. Growing high purity, well-aligned semiconducting CNTs is one of the important steps for realization of various applications and thus far, growth of CNTs with very few metallic CNTs for thin films and devices is yet to be fully realized. Since the choice of catalyst plays a significant role in the growth of CNTs, further research on different materials that can be used as catalysts is necessary to understand issues arising due to the tube-catalyst interactions. A major obstacle to commercial implementation of CNT (or graphene) nanoelectronics is rooted in the lack of an efficient and reliable method of device production and integration (cf. silicon integrated circuits). In addition, CNT electronics will likely have to compete with the emergence of silicon nanowires and related structures for integrated circuits in the near future as the rapid pace of Moore’s Law continues along with evolution and advances in semiconductor electronics and CMOS technology. Continued focus on the other allotropes of carbon like graphene (for 3D CNT-graphene networks used in, e.g. thermal interfaces) and fullerenes is necessary which may help in wide scale production and/or improvement in the properties of existing CNTs. For applications requiring macroscopic amounts of nanotubes, well-ordered assemblies will allow optimization of desired properties with nanoscale control. Lastly, since CNTs have not yet been fully used in large-scale commercial applications, not much is known about their possible effects on the human health and the surrounding environment [324] both during processing, post-processing and disposal [325,326,327]. Studies focusing on these aspects will also be necessary.
Conclusions
The superb (and unique) properties of CNTs and their potential use in a wide range of applications has led researchers to consider nanotubes based on carbon as one of the emerging materials that may play key roles in the future of nanoscale-based applications. This is supported by the CNT-related patent statistics between 2000 and 2017 (Fig. 47). In this review, we have focused on the progress made in the field of CNT fabrication, purification, assembly and integration of single and multiple tubes for their use in various applications. We discussed how structural control of individual CNT properties such as chirality, diameters and junctions are important factors in determining their properties (structural, electrical, mechanical, thermal properties and cost) and to utilize them for various applications. Also included is information related to post-growth purification techniques of CNTs using methods such as selective surface chemistry, gel chromatography and density gradient centrifugation. Assembly and integration for multiple CNTs using forest growth, catalyst patterning and composites are discussed. Details of their alignment/placement onto different substrates using methods such as photolithography, transfer printing and different solution-based techniques are also included. Towards the end, we list some emerging applications like sensors, field-effect devices, energy storage devices, health monitoring in aircraft structures, crypto primitives, commercial applications in the form of conductivity enhancement/control in plastics, in bio-based applications like tissue engineering, drug delivery, etc. based on their unique properties, advantages and challenges that need to be understood for efficient utilization of these structures in the future.
Significant progress has been made over the past two decades in CNT fabrication and assembly, from individual tubes to large ensembles and commercial applications should continue to grow as well-organized CNT materials are introduced. In terms of nanoscale integration, precise control of CNT type, placement and orientation will enable many applications in electronics and photonics and beyond, and despite challenges, continued advances in CNTs, with their almost ideal one-dimensional structure and properties, and related structures will play an important role in future applications of nanotechnology.
Availability of Data and Materials
Not applicable.
Abbreviations
- 1D:
-
One-dimensional
- 2D:
-
Two-dimensional
- 3D:
-
Three-dimensional
- AC:
-
Alternating current
- AFM:
-
Atomic force microscope
- CB:
-
Carbon black
- c-CVD:
-
Catalytic chemical vapor deposition
- CMC:
-
Carboxylmethyl cellulose
- CNTFET:
-
Carbon nanotube field-effect transistor
- CNTs:
-
Carbon nanotubes
- CVD:
-
Chemical vapor deposition
- DC:
-
Direct current
- DEP:
-
Dielectrophoresis
- DGU:
-
Density gradient ultracentrifugation
- DNA:
-
Deoxyribonucleic acid
- DOS:
-
Density of states
- FCCVD:
-
Floating catalyst chemical vapor deposition
- FETs:
-
Field-effect transistors
- HDPE:
-
High-density polyethylene
- ICs:
-
Integrated circuits
- IEX:
-
Ion-exchange chromatography
- IR:
-
Infrared
- LB:
-
Langmuir-Blodgett
- LCDs:
-
Liquid crystal displays
- m-SWCNTs:
-
Metallic single-walled carbon nanotubes
- MWCNTs:
-
Multi-walled carbon nanotubes
- N-CNTs:
-
Nitrogen-doped CNTs
- NIL:
-
Nano-imprint lithography
- NMPI:
-
4-(N-hydroxycarboxamido)-1-methylpyridinium iodide
- PBA:
-
Prussian blue analog
- PDMS:
-
Polydimethylsiloxane
- PECVD:
-
Plasma-enhanced chemical vapor deposition
- PET:
-
Polyethylene terephthalate
- PMMA:
-
Polymethyl methacrylate
- PTC:
-
Positive temperature coefficient
- PVA:
-
Polyvinyl alcohol
- PyC:
-
Pyrolytic carbon
- SDS:
-
Sodium dodecyl sulfate
- SEM:
-
Scanning electron microscopy/microscope
- SPX:
-
Spandex
- SSA:
-
Specific surface area
- ssDNA:
-
Single-stranded-deoxyribonucleic acid
- s-SWCNTs:
-
Semiconducting single-walled carbon nanotubes
- SWCNTs:
-
Single-walled carbon nanotubes
- TEM:
-
Transmission electron microscope
- THz:
-
Terahertz
- TPU:
-
Thermoplastic polyurethane
- UHMWPE:
-
Ultra-high molecular weight polyethylene
- UV:
-
Ultraviolet
- VHS:
-
Van Hove singularities
- VLS:
-
Vapor-liquid-solid
- VLSI:
-
Very-large-scale integrated
- VPE:
-
Vapor phase epitaxy
- VSS:
-
Vapor-solid-solid
References
Tanaka K, Iijima S (2014) Carbon nanotubes and graphene, Second, 2nd edn. Elsevier, Amsterdam
IEEE International roadmap for devices and systems: 2017 Edition.
Kroto HW, Fischer DCJE (1993) The fullerenes: new horizons for the chemistry, physics and astrophysics of carbon. Cambridge University Press, Cambridge
Kroto HW, Heath JR, O’Brien SC et al (1985) C60: Buckminsterfullerene. Nature 318:162–163
Fischer J, Dai H, Thess A et al (1997) Metallic resistivity in crystalline ropes of single-wall carbon nanotubes. Phys Rev B 55:R4921–R4924
Coleman JN, Khan U, Blau WJ, Gun’ko YK (2006) Small but strong: a review of the mechanical properties of carbon nanotube–polymer composites. Carbon 44:1624–1652
Martel R, Schmidt T, Shea H et al (1998) Single- and multi-wall carbon nanotube field-effect transistors. Appl Phys Lett 73:2447–2449
Frank B, Rinaldi A, Blume R et al (2010) Oxidation stability of multiwalled carbon nanotubes for catalytic applications. Chem Mater 22:4462–4470
Abdalla S, Al-Marzouki F, Al-Ghamdi AA, Abdel-Daiem A (2015) Different technical applications of carbon nanotubes. Nanoscale Res Lett 10:1–10
Peigney A, Laurent C, Flahaut E et al (2001) Specific surface area of carbon nanotubes and bundles of carbon nanotubes. Carbon 39:507–514
Wang X, Li Q, Xie J et al (2009) Fabrication of ultralong and electrically uniform single-walled carbon nanotubes on clean substrates. Nano Lett 9:3137–3141
Li F, Cheng H, Bai S et al (2000) Tensile strength of single-walled carbon nanotubes directly measured from their macroscopic ropes. Appl Phys Lett 77:3161–3163
Demczyk B, Wang Y, Cumings J et al (2002) Direct mechanical measurement of the tensile strength and elastic modulus of multiwalled carbon nanotubes. Mater Sci Eng A 334:173–178
Hone J, Llaguno MC, Biercuk MJ et al (2002) Thermal properties of carbon nanotubes and nanotube-based materials. Appl Phys A Mater Sci Process 74:339–343
Tang ZK, Zhang L, Wang N et al (2001) Superconductivity in 4 angstrom single-walled carbon nanotubes. Science 292:2462–2465
Ferrier M, De Martino A, Kasumov A et al (2004) Superconductivity in ropes of carbon nanotubes. Solid State Commun 131:615–623
Colomer J, Henrard L, Lambin P, Van Tendeloo G (2002) Electron diffraction and microscopy of single-wall carbon nanotube bundles produced by different methods. Eur Phys J B 27:111–118
Chen W, Liu P, Liu Y et al (2018) A temperature-induced conductive coating via layer-by-layer assembly of functionalized graphene oxide and carbon nanotubes for a flexible, adjustable response time flame sensor. Chem Eng J 353:115–125
Lourie O, Wagner HD (1998) Evaluation of Young's modulus of carbon nanotubes by micro-Raman spectroscopy. J Mater Res 13:2418–2422
Qian D, Wagner GJ, Liu WK, Ruoff RS (2002) Mechanics of carbon nanotubes. Appl Mech Rev 55:495–533
Li JQ, Zhang Q, Chen G, Yoon SF, Ahn J, Wang SG, Zhou Q, Wang Q (2002) Thermal conductivity of multiwalled carbon nanotubes. Phys Rev B 66(16):165440
Kalamkarov AL, Georgiades AV, Rokkam SK et al (2006) Analytical and numerical techniques to predict carbon nanotubes properties. Int J Solids Struct 43:6832–6854
Dresselhaus MS, Dresselhaus G, Eklund PC (1996) Science of fullerenes and carbon nanotubes. Academic, San Diego
Durkop T, Getty SA, Cobas E, Fuhrer MS (2004) Extraordinary mobility in semiconducting carbon nanotubes. Nano Lett 4(1):35–39
Lundstrom M, Wang Q, Javey A et al (2003) Ballistic carbon nanotube field-effect transistors. Nature 424:654–657
Wei BQ, Vajtai R, Ajayan PM (2001) Reliability and current carrying capacity of carbon nanotubes. Appl Phys Lett 79:1172
Subramaniam C, Yamada T, Kobashi K et al (2013) One hundred fold increase in current carrying capacity in a carbon nanotube-copper composite. Nat Commun 4:2202
Saito R, Dresselhaus G, Dresselhaus MS (1998) Physical properties of carbon nanotubes. Imperial College Press, London
Wilder JW, Dekker C, Venema LC, Rinzler AG, Smalley RE (1998) Electronic structure of atomically resolved carbon nanotubes. Nature 391:59–62
Wan R, Peng J, Zhang X, Leng C (2013) Band gaps and radii of metallic zigzag single wall carbon nanotubes. Phys B Condens Matter 417:1–3
Eremina VA, Obraztsov PA, Fedotov PV et al (2017) Separation and optical identification of semiconducting and metallic single-walled carbon nanotubes: separation of semiconducting and metallic SWCNTs. Phys Status Solidi B 254:1600659
Kataura H, Kumazawa Y, Maniwa Y et al (1999) Optical properties of single-wall carbon nanotubes. Synth Met 103:2555–2558
Saito R, Nugraha ART, Hasdeo EH et al (2016) Electronic and optical properties of single wall carbon nanotubes. Top Curr Chem 375:7
Ajayan PM, Terrones M, De la Guardia A et al (2002) Nanotubes in a flash: ignition and reconstruction. Science 296:705
Tseng SH, Tai NH, Hsu WK et al (2007) Ignition of carbon nanotubes using a photoflash. Carbon 45:958–964
Weisman R, Bachilo S (2003) Dependence of optical transition energies on structure for single-walled carbon nanotubes in aqueous suspension: an empirical Kataura plot. Nano Lett 3:1235–1238
Iakoubovskii K, Saito T, Minami N, Kazaoui S, Ueno T, Miyata Y, Yanagi K, Kataura H, Ohshima S (2006) IR-extended photoluminescence mapping of single-wall and double-wall carbon nanotubes. J Phys Chem B 110(35):17420–11742
Thomsen CRS (2006) Raman scattering in carbon nanotubes. In: Cardona M, Merlin R (eds) Light scattering in solid IX. Topics in applied physics. Springer, Berlin
Baughman RH, Zakhidov AA, de HWA (2002) Carbon nanotubes–the route toward applications. Science 297:787–792
Al-Rub RKA, Ashour AI, Tyson BM (2012) On the aspect ratio effect of multi-walled carbon nanotube reinforcements on the mechanical properties of cementitious nanocomposites. Constr Build Mater 35:647–655
Schönenberger C, Bachtold A, Strunk C et al (1999) Interference and interaction in multi-wall carbon nanotubes. Appl Phys A Mater Sci Process 69:283–295
Purewal M, Hong B, Ravi A et al (2007) Scaling of resistance and electron mean free path of single-walled carbon nanotubes. Phys Rev Lett 98:186808
Lekawa-Raus A, Patmore J, Kurzepa L et al (2014) Electrical properties of carbon nanotube based fibers and their future use in electrical wiring. Adv Funct Mater 24:3661–3682
Zhang Q, Huang J, Qian W et al (2013) The road for nanomaterials industry: a review of carbon kNanotube production, post-treatment, and bulk applications for composites and energy storage. Small 9:1237–1265
McEuen PL (1998) Nanotechnology carbon-based electronics. Nature 393:15–17
Kazmierski T, Zhou D, Al-Hashimi B, Ashburn P (2010) Numerically efficient modeling of CNT transistors with ballistic and nonballistic effects for circuit simulation. IEEE Trans Nanotechnol 9:99–107
Teo K, Milne W, Hasko D, Yang M (2005) Carbon nanotube Schottky diode and directionally dependent field-effect transistor using asymmetrical contacts. Appl Phys Lett 87:253116
Dekker C, Tans SJ, Verschueren ARM (1998) Room-temperature transistor based on a single carbon nanotube. Nature 393:49–52
Chiu W-C, Tsui B-Y (2014) High performance of CNT-interconnects by the multi-layer structure. Microelectron Reliab 54:778–784
Li H, Liu W, Cassell AM et al (2013) Low-resistivity long-length horizontal carbon nanotube bundles for interconnect applications-part I: process development. IEEE Trans Electron Devices 60:2862–2869
Cobas ED, Anlage SM, Fuhrer MS (2011) Single carbon nanotube Schottky diode microwave rectifiers. IEEE Trans Microwave Theory Tech 59:2726–2732
Li L, Zhou Y, Yang H, Zhou D, Zhou Y (2014) Progress in application of CNTs in lithium-ion batteries. J Nanomater 2014:1–8
Matthew RPR, Ganter Cory J, Cress Roberta D et al (2009) Carbon nanotubes for lithium ion batteries. Energy Environ Sci 6:638–654
Froudakis GE (2011) Hydrogen storage in nanotubes & nanostructures. Mater Today 14:324–328
Zaporotskova IV, Boroznina NP, Parkhomenko YN, Kozhitov LV (2016) Carbon nanotubes: sensor properties. a review. Mod Electron Mater 2:95–105
Fu W, Liu L, Jiang K et al (2010) Super-aligned carbon nanotube films as aligning layers and transparent electrodes for liquid crystal displays. Carbon 48:1876–1879
Chandrasekhar P (2018) CNT applications in displays and transparent, conductive films transparent, conductive films, CNT applications in/substrates. In: Conducting polymers, fundamentals and applications: including carbon nanotubes and graphene. Springer International Publishing, Cham, pp 73–75
Li Y, Wang S, Wang Q, Xing M (2018) Enhancement of fracture properties of polymer composites reinforced by carbon nanotubes: a molecular dynamics study. Carbon 129:504–509
Nguyen-Tran H-D, Yum YJ, Hoang V-T, Do V-T, Chun D-M (2018) Effect of multiwalled carbon nanotubes on the mechanical properties of carbon fiber-reinforced polyamide-6/polypropylene composites for lightweight automotive parts. Materials 11(3):429
Ji X, Chen D, Wang Q et al (2018) Synergistic effect of flame retardants and carbon nanotubes on flame retarding and electromagnetic shielding properties of thermoplastic polyurethane. Compos Sci Technol 163:49–55
Ma W, Liu L, Zhang Z et al (2009) High-strength composite fibers: realizing true potential of carbon nanotubes in polymer matrix through continuous reticulate architecture and molecular level couplings. Nano Lett 9:2855–2861
Chou T-W, Gao L, Thostenson ET et al (2010) An assessment of the science and technology of carbon nanotube-based fibers and composites. Compos Sci Technol 70:1–19
Zhang M, Wang W, Wu F et al (2017) Magnetic and fluorescent carbon nanotubes for dual modal imaging and photothermal and chemo-therapy of cancer cells in living mice. Carbon 123:70–83
Abreu B, Lamas B, Fonseca A et al (2014) Experimental characterization of convective heat transfer with MWCNT based nanofluids under laminar flow conditions. Heat Mass Transf 50:65–74
Jiang H-L, Lin Y-L, Li N et al (2018) Application of magnetic N-doped carbon nanotubes in solid-phase extraction of trace bisphenols from fruit juices. Food Chem 269:413–418
Portnoi ME, Kibis OV, da Costa MR (2008) Terahertz applications of carbon nanotubes. Superlattice Microst 43:399–407
da Costa MR, Kibis OV, Portnoi ME (2009) Carbon nanotubes as a basis for terahertz emitters and detectors. Microelectron J 40:776–778
Hartmann RR, Kono J, Portnoi ME (2014) Terahertz science and technology of carbon nanomaterials. Nanotechnology 25:322001
Bhatia R, Ujjain SK (2017) Soluble single-walled carbon nanotubes for photovoltaics. Mater Lett 190:165–168
Chen H, Lou J, Xi N, Bo S, Chen L, Lai KWC (2011) Infrared imaging using carbon nanotube based detector. Proc SPIE 8058:80580N–80580N-9
Khlobystov AN (2011) Carbon nanotubes: from nano test tube to Nano-reactor. ACS Nano 5:9306–9312
Partanen L, Murdachaew G, Laasonen K (2018) Oxygen evolution reaction kinetic barriers on nitrogen-doped carbon nanotubes. J Phys Chem C 122:12892–12899
Wu J, Xue Y, Yan X et al (2012) Co3O4 nanocrystals on single-walled carbon nanotubes as a highly efficient oxygen-evolving catalyst. Nano Res 5:521–530
Toma F, Sartorel A, Iurlo M et al (2011) Tailored functionalization of carbon nanotubes for electrocatalytic water splitting and sustainable energy applications. ChemSusChem 4:1447–1451
Man I, Su H, Calle-Vallejo F et al (2011) Universality in oxygen evolution electrocatalysis on oxide surfaces. ChemCatChem 3:1159–1165
Gong K, Du F, Xia Z et al (2009) Nitrogen-doped carbon nanotube arrays with high electrocatalytic activity for oxygen reduction. Science 323:760–764
Zhao Y, Nakamura R, Kamiya K et al (2013) Nitrogen-doped carbon nanomaterials as non-metal electrocatalysts for water oxidation. Nat Commun 4:2390
Iijima S (1991) Helical microtubules of graphitic carbon. Nature 354:56–58
Ando Y, Zhao X, Sugai T, Kumar M (2004) Growing carbon nanotubes. Mater Today 7:22–29
Ajayan PM, Ebbesen TW (1992) Large-scale synthesis of carbon nanotubes. Nature 358:220–222
Savoy R, de VMS, Klang CH et al (1993) Cobalt-catalysed growth of carbon nanotubes with single- atomic-layer walls. Nature 363:605–607
Ichihashi T, Iijima S (1993) Single-shell carbon nanotubes of 1-nm diameter. Nature 363:603–605
Ma J, Wang J-N, Tsai C-J et al (2010) Diameters of single-walled carbon nanotubes (SWCNTs) and related nanochemistry and nanobiology. Front Mater Sci China 4:17–28
Henley S, Anguita J, Silva S (2012) Synthesis of carbon nanotubes. Springer, Netherlands
Guo T, Nikolev P, Thess A et al (1995) Catalytic growth of single-walled nanotubes by laser vaporization. Chem Phys Lett 243:49–54
Guo T, Nikolev P, RinzlerR A et al (1995) Self-assembly of tubular fullerenes. J Phys Chem 99:10694–10697
Thess A, Lee R, Nikolaev P et al (1996) Crystalline ropes of metallic carbon nanotubes. Science 273:483–487
Hafner JH, Bronikowski MJ, Azamian BR et al (1998) Catalytic growth of single-wall carbon nanotubes from metal particles. Chem Phys Lett 296:195–202
Lebedkin S, Schweiss P, Renker B et al (2002) Single-wall carbon nanotubes with diameters approaching 6 nm obtained by laser vaporization. Carbon 40:417–423
Dupuis A-C (2005) The catalyst in the CCVD of carbon nanotubes-a review. Prog Mater Sci 50:929–961
Varshney D, Weiner BR, Morell G (2010) Growth and field emission study of a monolithic carbon nanotube/diamond composite. Carbon 48:3353–3358
Wang H, Yuan Y, Wei L et al (2015) Catalysts for chirality selective synthesis of single-walled carbon nanotubes. Carbon 81:1–19
Moisala A, Nasibulin AG, Kauppinen EI (2003) The role of metal nanoparticles in the catalytic production of single-walled carbon nanotubes-a review. J Phys Condens Matter 15:S3011–S3035
Jourdain V, Bichara C (2013) Current understanding of the growth of carbon nanotubes in catalytic chemical vapour deposition. Carbon 58:2–39
Wagner RS, Ellis WC (1964) Vapor-liquid-solid mechanism of single crystal growth. Appl Phys Lett 4:89–90
Rümmeli MH, Bachmatiuk A, Börrnert F et al (2011) Synthesis of carbon nanotubes with and without catalyst particles. Nanoscale Res Lett 6:1–9
Lu J, Miao J (2012) Growth mechanism of carbon nanotubes: a nano czochralski model. Nanoscale Res Lett 7:1–5
Dai H, Rinzler AG, Nikolaev P et al (1996) Single-wall nanotubes produced by metal-catalyzed disproportionation of carbon monoxide. Chem Phys Lett 260:471–475
Jose-Yacaman M, Miki-Yoshida M, Rendon L, Santiesteban JG (1993) Catalytic growth of carbon microtubules with fullerene structure. Appl Phys Lett 62:202–204
Kumar M, Ando Y (2010) Chemical vapor deposition of carbon nanotubes: a review on growth mechanism and mass production. J Nanosci Nanotechnol 10:3739–3758
Azam MA, Manaf NSA, Talib E, Bistamam MSA (2013) Aligned carbon nanotube from catalytic chemical vapor deposition technique for energy storage device: a review. Ionics 19:1455–1476
Kong J, Cassell AM, Dai H (1998) Chemical vapor deposition of methane for single-walled carbon nanotubes. Chem Phys Lett 292:567–574
Kunadian I, Andrews R, Qian D, Pinar Mengüç M (2009) Growth kinetics of MWCNTs synthesized by a continuous-feed CVD method. Carbon 47:384–395
Morjan RE, Nerushev OA, Sveningsson M, Rohmund F et al (2004) Growth of carbon nanotubes from C60. Appl Phys A 78:253–261
Cheung C, Kurtz A, Park H, Lieber C (2002) Diameter-controlled synthesis of carbon nanotubes. J Phys Chem B 106:2429–2433
Seidel R, Duesberg G, Unger E et al (2004) Chemical vapor deposition growth of single-walled carbon nanotubes at 600 degrees C and a simple growth model. J Phys Chem B 108:1888–1893
Willems I, Kónya Z, Colomer J et al (2000) Control of the outer diameter of thin carbon nanotubes synthesized by catalytic decomposition of hydrocarbons. Chem Phys Lett 317:71–76
Pint C, Pheasant S, Pasquali M et al (2008) Synthesis of high aspect-ratio carbon nanotube “flying carpets” from nanostructured flake substrates. Nano Lett 8:1879–1883
Li WZ, Wen JG, Ren ZF (2002) Effect of temperature on growth and structure of carbon nanotubes by chemical vapor deposition. Appl Phys A 74:397–402
Liu B, Wu F, Gui H et al (2017) Chirality-controlled synthesis and applications of single-wall carbon nanotubes. ACS Nano 11:31–53
Omachi H, Segawa Y, Itami K (2012) Synthesis of cycloparaphenylenes and related carbon nanorings: a step toward the controlled synthesis of carbon nanotubes. Acc Chem Res 45:1378–1389
Arenal R, Lothman P, Picher M et al (2012) Direct evidence of atomic structure conservation along ultra-long carbon nanotubes. J Phys Chem C 116:14103–14107
Li Y, Mann D, Rolandi M et al (2004) Preferential growth of semiconducting single-walled carbon nanotubes by a plasma enhanced CVD method. Nano Lett 4:317–321
Ding L, Tselev A, Wang J et al (2009) Selective growth of well-aligned semiconducting single-walled carbon nanotubes. Nano Lett 9:800–805
Wong E, Bronikowski M, Hoenk M et al (2005) Submicron patterning of iron nanoparticle monolayers for carbon nanotube growth. Chem Mater 17:237–241
Smalley R, Li Y, Moore V et al (2006) Single wall carbon nanotube amplification: En route to a type-specific growth mechanism. J Am Chem Soc 128:15824–15829
Takagi D, Hibino H, Suzuki S et al (2007) Carbon nanotube growth from semiconductor nanoparticles. Nano Lett 7:2272–2275
Yao Y, Feng C, Zhang J, Liu Z (2009) “Cloning” of single-walled carbon nanotubes via open-end growth mechanism. Nano Lett 9:1673–1677
Bachilo S, Balzano L, Herrera J et al (2003) Narrow (n,m)-distribution of single-walled carbon nanotubes grown using a solid supported catalyst. J Am Chem Soc 125:11186–11187
He M, Jiang H, Liu B et al (2013) Chiral-selective growth of single-walled carbon nanotubes on lattice-mismatched epitaxial cobalt nanoparticles. Sci Rep 3:1460
Fouquet M, Bayer BC, Esconjauregui S et al (2012) Highly chiral-selective growth of single-walled carbon nanotubes with a simple monometallic co catalyst. Phys Rev B 85:23
Liu B, Ren W, Li S et al (2012) High temperature selective growth of single-walled carbon nanotubes with a narrow chirality distribution from a CoPt bimetallic catalyst. Chem Commun 48:2409–2411
Wang H, Wang B, Quek X et al (2010) Selective synthesis of (9,8) single walled carbon nanotubes on cobalt incorporated TUD-1 catalysts. J Am Chem Soc 132:16747–16749
Yang F, Wang X, Zhang D et al (2014) Chirality-specific growth of single-walled carbon nanotubes on solid alloy catalysts. Nature 510:522
Sakurai S, Yamada M, Sakurai H et al (2016) A phenomenological model for selective growth of semiconducting single-walled carbon nanotubes based on catalyst deactivation. Nanoscale 8:1015–1023
Omachi H, Nakayama T, Takahashi E et al (2013) Initiation of carbon nanotube growth by well-defined carbon nanorings. Nat Chem 5:572–576
Scott L, Jackson E, Zhang Q et al (2012) A short, rigid, structurally pure carbon nanotube by stepwise chemical synthesis. J Am Chem Soc 134:107–110
Zhang F, Hou P-X, Liu C, Cheng H-M (2016) Epitaxial growth of single-wall carbon nanotubes. Carbon 102:181–197
Yu X, Zhang J, Choi W et al (2010) Cap formation engineering: from opened C60 to single-walled carbon nanotubes. Nano Lett 10:3343
Liu B, Liu J, Li H et al (2015) Nearly exclusive growth of small diameter semiconducting single-wall carbon nanotubes from organic chemistry synthetic end-cap molecules. Nano Lett 15:586–595
Sanchez-Valencia J, Dienel T, Groning O et al (2014) Controlled synthesis of single-chirality carbon nanotubes. Nature 512:61
Hároz EH, Duque JG, Barros EB et al (2015) Asymmetric excitation profiles in the resonance Raman response of armchair carbon nanotubes. Phys Rev B 91:205446
Tu X, Walker A, Khripin C, Zheng M (2011) Evolution of DNA sequences toward recognition of metallic armchair carbon nanotubes. J Am Chem Soc 133:12998–13001
Khalilov U, Bogaerts A, Neyts E (2015) Atomic scale simulation of carbon nanotube nucleation from hydrocarbon precursors. Nat Commun 6:10306
Hata K, Futaba DN, Mizuno K et al (2004) Water-assisted highly efficient synthesis of impurity-free single-walled carbon nanotubes. Science 306:1362–1364
Li-Pook-Than A, Finnie P (2015) Observation of the metallic-type selective etching of single walled carbon nanotubes by real-time in situ two-laser Raman spectroscopy. Carbon 89:232–241
Yu B, Liu C, Hou P, Tian Y, Li S, Liu B, Li F et al (2011) Bulk synthesis of large diameter semiconducting single-walled carbon nanotubes by oxygen-assisted floating catalyst chemical vapor deposition. J Am Chem Soc 133:5232–5235
Zhang F, Hou P, Liu C et al (2016) Growth of semiconducting single-wall carbon nanotubes with a narrow band-gap distribution. Nat Commun 7:11160
Zhang G, Qi P, Wang X et al (2006) Selective etching of metallic carbon nanotubes by gas-phase reaction. Science 314:974–977
Li J, Ke C, Liu K et al (2014) Importance of diameter control on selective synthesis of semiconducting single-walled carbon nanotubes. ACS Nano 8:8564–8572
Zhu YT, Zhang J, Liu Z et al (2007) Temperature-mediated growth of single-walled carbon-nanotube intramolecular junctions. Nat Mater 6:283–286
Tian Y, Timmermans MY, Kauppinen EI et al (2011) Tailoring the diameter of single-walled carbon nanotubes for optical applications. Nano Res 4:807–815
Sinnott SB, Andrews R, Qian D et al (1999) Model of carbon nanotube growth through chemical vapor deposition. Chem Phys Lett 315:25–30
Durrer L, Greenwald J, Helbling T et al (2009) Narrowing SWNT diameter distribution using size-separated ferritin-based Fe catalysts. Nanotechnology 20:355601
Song W, Jeon C, Kim Y et al (2010) Synthesis of bandgap-controlled semiconducting single-walled carbon nanotubes. ACS Nano 4:1012–1018
Fort E, Scott L (2011) Carbon nanotubes from short hydrocarbon templates. Energy analysis of the diels-alder cycloaddition/rearomatization growth strategy. J Mater Chem 21:1373–1381
Jasti R, Bertozzi CR (2010) Progress and challenges for the bottom-up synthesis of carbon nanotubes with discrete chirality. Chem Phys Lett 494:1–7
Li H, Page A, Irle S, Morokuma K (2012) Single-walled carbon nanotube growth from chiral carbon Nanorings: prediction of chirality and diameter influence on growth rates. J Am Chem Soc 134:15887–15896
Thostenson ET, Ren Z, Chou T-W (2001) Advances in the science and technology of carbon nanotubes and their composites: a review. Compos Sci Technol 61:1899–1912
Javey A, Dai H (2005) Regular arrays of 2 nm metal nanoparticles for deterministic synthesis of nanomaterials. J Am Chem Soc 127:11942–11943
He D, Bozlar M, Genestoux M, Bai J (2010) Diameter- and length-dependent self-organizations of multi-walled carbon nanotubes on spherical alumina microparticles. Carbon 48:1159–1170
Li Y, Ma C, Kang J et al (2017) Preparation of diameter-controlled multi-wall carbon nanotubes by an improved floating-catalyst chemical vapor deposition method. Carbon 124:726
Venkatesan S, Visvalingam B, Mannathusamy G et al (2018) Effect of chemical vapor deposition parameters on the diameter of multi-walled carbon nanotubes. Int Nano Lett 8:297–308
Ren ZF, Huang ZP, Xu JW et al (1998) Synthesis of large arrays of well-aligned carbon nanotubes on glass. Science 282:1105–1107
Palm T, Thylén L (1992) Analysis of an electron-wave Y-branch switch. Appl Phys Lett 60:237–239
Daraio C, Jin S, Bandaru PR, Rao AM (2005) Novel electrical switching behaviour and logic in carbon nanotube Y-junctions. Nat Mater 4:663–666
Soltman D, Wang D, Xu J et al (2005) Differential current amplification in three-terminal Y-junction carbon nanotube devices. Appl Phys Lett 87:123504
Andriotis AN, Menon M, Srivastava D, Chernozatonskii L (2001) Rectification properties of carbon nanotube “Y-junctions”. Phys Rev Lett 87:066802
Papadopoulos C, Rakitin A, Li J et al (2000) Electronic transport in Y-junction carbon nanotubes. Phys Rev Lett 85:3476–3479
Li J, Papadopoulos C, Xu J (1999) Growing Y-junction carbon nanotubes. Nature 402:253–254
Gothard N, Daraio C, Gaillard J et al (2004) Controlled growth of Y-junction nanotubes using Ti-doped vapor catalyst. Nano Lett 4:213–217
Terrones M, Banhart F, Grobert N et al (2002) Molecular junctions by joining single-walled carbon nanotubes. Phys Rev Lett 89:075505
Banhart F (2001) The formation of a connection between carbon nanotubes in an electron beam. Nano Lett 1:329–332
Jang M, Kim S, Jeong H, Ju S-Y (2016) Affinity-mediated sorting order reversal of single-walled carbon nanotubes in density gradient ultracentrifugation. Nanotechnology 27:41LT01
Nikitskiy I, Chernov A, Obraztsova E (2012) Sorting carbon nanotubes by density gradient ultracentrifugation. J Nanoelectron Optoelectron 7:46–49
Arnold M, Green A, Hulvat J et al (2006) Sorting carbon nanotubes by electronic structure using density differentiation. Nat Nanotechnol 1:60–65
Brakke MK, Daly JM (1965) Density-gradient centrifugation: non-ideal sedimentation and the interaction of major and minor components. Science 148:387–389
Bonaccorso F, Hasan T, Tan PH et al (2010) Density gradient ultracentrifugation of nanotubes: interplay of bundling and surfactants encapsulation. J Phys Chem C 114:17267–17285
Zheng M, Tu X, Jagota A, Manohar S (2009) DNA sequence motifs for structure-specific recognition and separation of carbon nanotubes. Nature 460:250–253
Zheng M (2017) Sorting carbon nanotubes. Top Curr Chem 375:13
Lustig SR, Jagota A, Khripin C, al e (2005) Theory of structure-based carbon nanotube separations by ion-exchange chromatography of DNA/CNT hybrids. J Phys Chem B 109(7):2559–2566
Yahya I, Bonaccorso F, Clowes SK et al (2015) Temperature dependent separation of metallic and semiconducting carbon nanotubes using gel agarose chromatography. Carbon 93:574–594
Liu H, Tanaka T, Kataura H (2014) Optical isomer separation of single-chirality carbon nanotubes using gel column chromatography. Nano Lett 14:6237–6243
Silvera-Batista C, Scott D, McLeod S, Ziegler K (2011) A mechanistic study of the selective retention of SDS-suspended single-wall carbon nanotubes on agarose gels. J Phys Chem C 115:9361–9369
Moshammer K, Hennrich F, Kappes M (2009) Selective suspension in aqueous sodium dodecyl sulfate according to electronic structure type allows simple separation of metallic from semiconducting single-walled carbon nanotubes. Nano Res 2:599–606
Liu H, Nishide D, Tanaka T, Kataura H (2011) Large-scale single-chirality separation of single-wall carbon nanotubes by simple gel chromatography. Nat Commun 2:309
Cui J, Yang D, Zeng X et al (2017) Recent progress on the structure separation of single-wall carbon nanotubes. Nanotechnology 28:452001
Yang Z, Yang B, Zhao Z et al (2014) The assembly of carbon nanotubes by dielectrophoresis: insights into the dielectrophoretic nanotube-nanotube interactions. Physica E 56:117–122
Iakoubovskii K (2009) Techniques of aligning carbon nanotubes. Open Phys 7:645–653
Yamamoto K, Akita S, Nakayama Y (1998) Orientation and purification of carbon nanotubes using ac electrophoresis. J Phys D Appl Phys 31:L34
Krupke R, Hennrich F, Löhneysen HV, Kappes MM (2003) Separation of metallic from semiconducting single-walled carbon nanotubes. Science 301:344–347
Hersam MC (2008) Progress towards monodisperse single-walled carbon nanotubes. Nat Nanotechnol 3:387–394
Wang H, Bao Z (2015) Conjugated polymer sorting of semiconducting carbon nanotubes and their electronic applications. Nano Today 10:737–758
Franklin N, Dai H (2000) An enhanced CVD approach to extensive nanotube networks with directionality. Adv Mater 12:890–894
Kong J, Zhou C, Morpurgo A et al (1999) Synthesis, integration, and electrical properties of individual single-walled carbon nanotubes. Appl Phys A Mater Sci Process 69:305–308
Papadopoulos C (2012) Carbon nanotube pattern formation-precise routing on silicon oxide using nanoscale catalyst breadboards. IEEE Trans Nanotechnol 11:1212–1216
Sangwan V, Ballarotto V, Hines D et al (2014) Controlled growth, patterning and placement of carbon nanotube thin films (vol 54, pg 1204, 2010). Solid State Electron 93:66
Castan A, Forel S, Catala L et al (2017) New method for the growth of single-walled carbon nanotubes from bimetallic nanoalloy catalysts based on Prussian blue analog precursors. Carbon 123:583–592
Guo L (2007) Nanoimprint lithography: methods and material requirements. Adv Mater 19:495–513
Choi D, Choi J, Jung S et al (2008) Direct soft UV-NIL with resist incorporating carbon nanotubes. Microelectron Eng 85:195–201
Saleem AM, Berg J, Desmaris V, Kabir MS (2009) Nanoimprint lithography using vertically aligned carbon nanostructures as stamps. Nanotechnology 20:375302
Legagneux P, Gröning O, Milne W et al (2006) Investigation of field emission properties of carbon nanotube arrays defined using nanoimprint lithography. Appl Phys Lett 89:022111
Yu C-C, Chen H-L (2015) Nanoimprint technology for patterning functional materials and its applications. Microelectron Eng 132:98–119
Ionescu R, Marks R, Gheber L (2005) Manufacturing of nanochannels with controlled dimensions using protease nanolithography. Nano Lett 5:821–827
Kuljanishvili I, Dikin D, Rozhok S et al (2009) Controllable patterning and CVD growth of isolated carbon nanotubes with direct parallel writing of catalyst using dip-pen nanolithography. Small 5:2523–2527
Omrane B, Papadopoulos C (2010) A direct-write approach for carbon nanotube catalyst deposition. IEEE Trans Nanotechnol 9:375–380
Papadopoulos C, Omrane B (2008) Nanometer-scale catalyst patterning for controlled growth of individual single-walled carbon nanotubes. Adv Mater 20:1344
Hart AJ, Slocum AH, Royer L (2006) Growth of conformal single-walled carbon nanotube films from Mo/Fe/Al2O3 deposited by electron beam evaporation. Carbon 44:348–359
Ural A, Li Y, Dai H (2002) Electric-field-aligned growth of single-walled carbon nanotubes on surfaces. Appl Phys Lett 81:3464–3466
Huang S, Cai X, Liu J (2003) Growth of millimeter-long and horizontally aligned single-walled carbon nanotubes on flat substrates. J Am Chem Soc 125:5636–5637
Huang S, Woodson M, Smalley R, Liu J (2004) Growth mechanism of oriented long single walled carbon nanotubes using “fast-heating” chemical vapor deposition process. Nano Lett 4:1025–1028
Huang S, Maynor B, Cai X, Liu J (2003) Ultralong, well-aligned single-walled carbon nanotube Architectureson surfaces. Adv Mater 15:1651–1655
Kim W, Choi H, Shim M et al (2002) Synthesis of ultralong and high percentage of semiconducting single-walled carbon nanotubes. Nano Lett 2:703–708
Kocabas C, Hur S, Gaur A et al (2005) Guided growth of large-scale, horizontally aligned arrays of single-walled carbon nanotubes and their use in thin-film transistors. Small 1:1110–1116
Han S, Liu X, Zhou C (2005) Template-free directional growth of single-walled carbon nanotubes on a- and r-plane sapphire. J Am Chem Soc 127:5294–5295
Ago H, Nakamura K, Ikeda K et al (2005) Aligned growth of isolated single-walled carbon nanotubes programmed by atomic arrangement of substrate surface. Chem Phys Lett 408:433–438
Kang S, Kocabas C, Ozel T et al (2007) High-performance electronics using dense, perfectly aligned arrays of single-walled carbon nanotubes. Nat Nanotechnol 2:230–236
Kong J, Franklin NR, Zhou C et al (2000) Nanotube molecular wires as chemical sensors. Science 287:622–625
Qu L, Dai L, Stone M et al (2008) Carbon nanotube arrays with strong shear binding-on and easy normal lifting-off. Science 322:238–242
Choo H, Jung Y, Jeong Y, et al (2012) Fabrication and Applications of Carbon Nanotube Fibers. Carbon Lett 13:191–204
Murali R, Brenner K, Meindl J, et al (2009) Breakdown current density of graphene nanoribbons. Appl Phys Lett 94:243114–3
Galvan D, Hirata G, Adem E (2006) Microstructural and chemical analysis performed by HRTEM and EDS on YBa2Cu3O7-x/ag films irradiated with electrons. Mater Sci Eng B 126:28–32
Anguita JV, Cox DC, Ahmad M et al (2013) Highly Transmissive carbon nanotube forests grown at low substrate temperature. Adv Funct Mater 23:5502–5509
Yasuda S, Futaba D, Yamada T et al (2009) Improved and large area single-walled carbon nanotube forest growth by controlling the gas flow direction. ACS Nano 3:4164–4170
Li WZ, Wang DZ, Yang SX et al (2001) Controlled growth of carbon nanotubes on graphite foil by chemical vapor deposition. Chem Phys Lett 335:141–149
Amama P, Pint C, Kim S et al (2010) Influence of alumina type on the evolution and activity of alumina-supported Fe catalysts in single-walled carbon nanotube carpet growth. ACS Nano 4:895–904
Fujisawa K, Kim H, Go S et al (2016) A review of double-walled and triple-walled carbon nanotube synthesis and applications. Appl Sci 6:109
Yamada T, Namai T, Hata K et al (2006) Size-selective growth of double-walled carbon nanotube forests from engineered iron catalysts. Nat Nanotechnol 1:131–136
Zhang M, Atkinson KR, Baughman RH (2004) Multifunctional carbon nanotube yarns by downsizing an ancient technology. Science 306:1358–1361
Yamazaki Y, Katagiri M, Sakuma N et al (2010) Synthesis of a closely packed carbon nanotube forest by a multi-step growth method using plasma-based chemical vapor deposition. Appl Phys Express 3:055002
Yamamoto N, Hart AJ, Garcia EJ et al (2009) High-yield growth and morphology control of aligned carbon nanotubes on ceramic fibers for multifunctional enhancement of structural composites. Carbon 47:551–560
Ismagilov RR, Shvets PV, Zolotukhin AA (2013) Growth of a carbon nanotube forest on silicon using remote plasma CVD. Chem Vap Depos 19(10-11-12):332-337
Zhang G, Mann D, Zhang L et al (2005) Ultra-high-yield growth of vertical single-walled carbon nanotubes: hidden roles of hydrogen and oxygen. Proc Natl Acad Sci U S A 102:16141–16145
Zhong G, Warner JH, Fouquet M et al (2012) Growth of ultrahigh density single-walled carbon nanotube forests by improved catalyst design. ACS Nano 6:2893–2903
Suh J, Lee J (1999) Highly ordered two-dimensional carbon nanotube arrays. Appl Phys Lett 75:2047–2049
Sui Y, Acosta D, Gonzalez-Leon J et al (2001) Structure, thermal stability, and deformation of multibranched carbon nanotubes synthesized by CVD in the AAO template. J Phys Chem B 105:1523–1527
Li J, Papadopoulos C, Xu J, Moskovits M (1999) Highly-ordered carbon nanotube arrays for electronics applications. Appl Phys Lett 75:367–369
Dai L, Patil A, Gong X et al (2003) Aligned nanotubes. ChemPhysChem 4:1150–1169
Jo J, Jung J, Lee J, Jo W (2010) Fabrication of highly conductive and transparent thin films from single-walled carbon nanotubes using a new non-ionic surfactant via spin coating. ACS Nano 4:5382–5388
Wang Q, Moriyama H (2011) Carbon nanotube-based thin films: synthesis and properties. In: Yellampalli S (ed) Carbon Nanotubes. IntechOpen. https://doi.org/10.5772/22021
Boccaccini AR, Cho J, Roether JA et al (2006) Electrophoretic deposition of carbon nanotubes. Carbon 44:3149–3160
Rahy A, Choudhury A, Kim C et al (2014) A simple/green process for the preparation of composite carbon nanotube fibers/yarns. RSC Adv 4:43235–43240
Faraji S, Stano K, Yildiz O et al (2015) Ultralight anisotropic foams from layered aligned carbon nanotube sheets. Nanoscale 7:17038–17047
Worsley M, Stadermann M, Wang Y et al (2010) High surface area carbon aerogels as porous substrates for direct growth of carbon nanotubes. Chem Commun 46:9253–9255
Hou Y, Tang J, Zhang H et al (2009) Functionalized few-walled carbon nanotubes for mechanical reinforcement of polymeric composites. ACS Nano 3:1057–1062
Byrne M, Gun’ko Y (2010) Recent advances in research on carbon nanotube-polymer composites. Adv Mater 22:1672–1688
Habisreutinger S, Leijtens T, Eperon G et al (2014) Carbon nanotube/polymer composites as a highly stable hole collection layer in perovskite solar cells. Nano Lett 14:5561–5568
Santos JCC, Mansur AAP, Ciminelli VST, Mansur HS (2014) Nanocomposites of poly (vinyl alcohol)/functionalized-multiwall carbon nanotubes conjugated with glucose oxidase for potential application as scaffolds in skin wound healing. Int J Polym Mater Polym Biomater 63:185–196
Du F, Fischer J, Winey K (2003) Coagulation method for preparing single-walled carbon nanotube/poly (methyl methacrylate) composites and their modulus, electrical conductivity, and thermal stability. J Polym Sci B Polym Phys 41:3333–3338
Kharissova O, Kharisov B, Ortiz E (2013) Dispersion of carbon nanotubes in water and non-aqueous solvents. RSC Adv 3:24812–24852
Papadopoulos C (2016) Nanofabrication: principles and applications. Springer International Publishing, Cham
Alig I, Pötschke P, Lellinger D et al (2012) Establishment, morphology and properties of carbon nanotube networks in polymer melts. Polymer 53:4–28
Meincke O, Kaempfer D, Weickmann H et al (2004) Mechanical properties and electrical conductivity of carbon-nanotube filled polyamide-6 and its blends with acrylonitrile/butadiene/styrene. Polymer 45:739–748
Bekyarova E, Thostenson E, Yu A et al (2007) Multiscale carbon nanotube-carbon fiber reinforcement for advanced epoxy composites. Langmuir 23:3970–3974
Zeng Y, Lu G, Wang H et al (2015) Positive temperature coefficient thermistors based on carbon nanotube/polymer composites. Sci Rep 4:6684
Moniruzzaman M, Winey K (2006) Polymer nanocomposites containing carbon nanotubes. Macromolecules 39:5194–5205
Velasco-Santos C, Martinez-Hernandez A, Fisher F et al (2003) Improvement of thermal and mechanical properties of carbon nanotube composites through chemical functionalization. Chem Mater 15:4470–4475
Jia Z, Wang Z, Xu C et al (1999) Study on poly (methyl methacrylate)/carbon nanotube composites. Mater Sci Eng A 271:395–400
Allen R, Pan L, Fuller G, Bao Z (2014) Using in-situ polymerization of conductive polymers to enhance the electrical properties of solution-processed carbon nanotube films and fibers. ACS Appl Mater Interfaces 6:9966–9974
Xia H, Wang Q, Li K, Hu G (2004) Preparation of polypropylene/carbon nanotube composite powder with a solid-state mechanochemical pulverization process. J Appl Polym Sci 93:378–386
Regev O, Elkati P, Loos JJ, Koning CC (2004) Preparation of conductive nanotube-polymer composites using latex technology. Adv Mater 16:248
Clancy A, Anthony D, Fisher S et al (2017) Reductive dissolution of supergrowth carbon nanotubes for tougher nanocomposites by reactive coagulation spinning. Nanoscale 9:8764–8773
Bai Y, Neupane M, Park I et al (2010) Electrophoretic deposition of carbon nanotubes-hydroxyapatite nanocomposites on titanium substrate. Mater Sci Eng C 30:1043–1049
Yamada T, Hiraoka T, Hata K et al (2006) Shape-engineerable and highly densely packed single-walled carbon nanotubes and their application as super-capacitor electrodes. Nat Mater 5:987–994
Gui X, Cao A, Wei J et al (2010) Soft, highly conductive nanotube sponges and composites with controlled compressibility. ACS Nano 4:2320–2326
Mukhopadhyay SM, Karumuri A, Barney IT (2009) Hierarchical nanostructures by nanotube grafting on porous cellular surfaces. J Phys D Appl Phys 42:195503
Fang J, Dong L, Dong W, et al (2015) Freeze-drying method prepared UHMWPE/CNTs composites with optimized micromorphologies and improved tribological performance. J Appl Polym Sci 132:18 41885
Nakagawa K (2011) Foam materials made from carbon nanotubes. In: Bianco S (ed) Carbon nanotubes. IntechOpen, Rijeka. https://doi.org/10.5772/18442
Yang Y, Gupta M (2005) Novel carbon nanotube-polystyrene foam composites for electromagnetic interference shielding. Nano Lett 5:2131–2134
Shaffer M, Windle A (1999) Fabrication and characterization of carbon nanotube/poly (vinyl alcohol) composites. Adv Mater 11:937–937
Faraji S, Stano K, Akyildiz H et al (2018) Modifying the morphology and properties of aligned CNT foams through secondary CNT growth. Nanotechnology 29:295602
Kim H, Lee J, Sim H (2016) Temperature-Responsive Tensile Actuator Based on Multi-walled Carbon NanotubeYarn. Nano-Micro Letters 8:254-259
Mirvakili S, Hunter I (2017) Fast Torsional Artificial Muscles from NiTi Twisted Yarns. ACS Applied Materials and Interfaces 9:16321-16326
Foroughi J, Spinks GM, Antiohos D et al (2014) Highly conductive carbon nanotube-graphene hybrid yarn. Adv Funct Mater 24:5859–5865
Truong TK, Lee Y, Suh D (2016) Multifunctional characterization of carbon nanotube sheets, yarns, and their composites. Curr Appl Phys 16:1250–1258
Jung Y, Cho YS, Lee JW et al (2018) How can we make carbon nanotube yarn stronger? Compos Sci Technol 166:95–108
Edwards SL, Church JS, Werkmeister JA, Ramshaw JAM (2009) Tubular micro-scale multiwalled carbon nanotube-based scaffolds for tissue engineering. Biomaterials 30:1725–1731
Li Y-L, Kinloch IA, Windle AH (2004) Direct spinning of carbon nanotube fibers from chemical vapor deposition synthesis. Science 304:276–278
Zhang M, Fang S, Zakhidov AA et al (2005) Strong, transparent, multifunctional, carbon nanotube sheets. Science 309:1215–1219
Miao M (2013) Yarn spun from carbon nanotube forests: production, structure, properties and applications. Particuology 11:378–393
Foroughi J, Spinks G, Aziz S et al (2016) Knitted carbon-nanotube-sheath/spandex-Core elastomeric yarns for artificial muscles and strain sensing. ACS Nano 10:9129–9135
Chen H, Roy A, Baek J-B et al (2010) Controlled growth and modification of vertically-aligned carbonanotubes for multifunctional applications. Mater Sci Eng R 70:63–91
Meitl M, Zhou Y, Gaur A et al (2004) Solution casting and transfer printing single-walled carbon nanotube films. Nano Lett 4:1643–1647
Sangwan VK, Southard A, Moore TL et al (2011) Transfer printing approach to all-carbon nanoelectronics. Microelectron Eng 88:3150–3154
Xia Y, Whitesides G (1998) Soft lithography. Angewandte Chemie- Internation Edition, vol 37, pp 550–575
Mangalum A, Rahman M, Norton M (2013) Site-specific immobilization of single-walled carbon nanotubes onto single and one-dimensional DNA origami. J Am Chem Soc 135:2451–2454
Zhao Z, Liu Y, Yan H (2013) DNA origami templated self-assembly of discrete length single wall carbon nanotubes. Org Biomol Chem 11:596–598
Eskelinen A, Kuzyk A, Kaltiaisenaho T et al (2011) Assembly of single-walled carbon nanotubes on DNA-origami templates through streptavidin-biotin interaction. Small 7:746–750
Song J-W, Kim J, Yoon Y-H et al (2008) Inkjet printing of single-walled carbon nanotubes and electrical characterization of the line pattern. Nanotechnology 19:095702
Michelis F, Bodelot L, Bonnassieux Y, Lebental B (2015) Highly reproducible, hysteresis-free, flexible strain sensors by inkjet printing of carbon nanotubes. Carbon 95:1020–1026
Chen K, Gao W, Emaminejad S, et al (2016) Printed carbon nanotube electronics and sensor systems. Adv Mater 28:4397-4414
Abdelhalim A, Abdellah A, Scarpa G, Lugli P (2013) Fabrication of carbon nanotube thin films on flexible substrates by spray deposition and transfer printing. Carbon 61:72–79
Talham DR (2004) Conducting and magnetic Langmuir-Blodgett films. Chem Rev 104:5479–5502
Kim Y, Minami N, Zhu W et al (2003) Langmuir-Blodgett films of single-wall carbon nanotubes: layer-by-layer deposition and in-plane orientation of tubes. Jpn J Appl Phys Part 1 42:7629–7634
Jin S, Dunham S, Song J et al (2013) Using nanoscale thermocapillary flows to create arrays of purely semiconducting single-walled carbon nanotubes. Nat Nanotechnol 8:347–355
Park H, Afzali A, Han S et al (2012) High-density integration of carbon nanotubes via chemical self-assembly. Nat Nanotechnol 7:787–791
Shulaker M, Hills G, Patil N et al (2013) Carbon nanotube computer. Nature 501:526
De Volder MFL, Tawfick SH, Baughman RH, Hart AJ (2013) Carbon nanotubes: present and future commercial applications. Science 339:535–539
Gojny F, Wichmann M, Kopke U et al (2004) Carbon nanotube-reinforced epoxy-compo sites: enhanced stiffness and fracture toughness at low nanotube content. Compos Sci Technol 64:2363–2371
Gillespie (2013) System and methods for use in monitoring a structure, US9329021B1
Jammalamadaka U, Tappa K, Jammalamadaka U, Tappa K (2018) Recent advances in biomaterials for 3D printing and tissue engineering. J Funct Biomater 9:16
Servant A, Jacobs I, Bussy C et al (2016) Gadolinium-functionalised multi-walled carbon nanotubes as a T1 contrast agent for MRI cell labelling and tracking. Carbon 97:126–133
Gong H, Peng R, Liu Z (2013) Carbon nanotubes for biomedical imaging: the recent advances. Adv Drug Deliv Rev 65:1951–1963
Zanello L, Zhao B, Hu H, Haddon R (2006) Bone cell proliferation on carbon nanotubes. Nano Lett 6:562–567
Usui Y, Aoki K, Narita N et al (2008) Carbon nanotubes with high bone-tissue compatibility and bone-formation acceleration effects. Small 4:240–246
Zhang X, Prasad S, Niyogi S et al (2005) Guided neurite growth on patterned carbon nanotubes. Sens Actuators B 106:843–850
Zhang W, Zhang Z, Zhang Y (2011) The application of carbon nanotubes in target drug delivery systems for cancer therapies. Nanoscale Res Lett 6:1–22
Zhong YP, Yingge ZM, Yanlian YP et al (2010) Pharmacological and toxicological target organelles and safe use of single-walled carbon nanotubes as drug carriers in treating Alzheimer disease. Nanomed Nanotechnol Biol Med 6:427–441
Wind S, Appenzeller J, Martel R et al (2002) Vertical scaling of carbon nanotube field-effect transistors using top gate electrodes. Appl Phys Lett 80:3817–3819
Kauppinen EI, Sun D, Kishimoto S et al (2011) Flexible high-performance carbon nanotube integrated circuits. Nat Nanotechnol 6:156–161
Pei T, Zhang P, Zhang Z et al (2014) Modularized construction of general integrated circuits on individual carbon nanotubes. Nano Lett 14:3102–3109
Zhong S, Hu J, Wu Z, Mei W (2015) Performance of lithium ion batteries using a carbon nanotube film as a cathode current collector. Carbon 81:852
Mirri F, Ma A, Hsu T et al (2012) High-performance carbon nanotube transparent conductive films by scalable dip coating. ACS Nano 6:9737–9744
Kiang CH, Dillon AC, Heben MJ et al (1997) Storage of hydrogen in single-walled carbon nanotubes. Nature 386:377–379
Kreupl F, Graham AP, Duesberg GS et al (2002) Carbon nanotubes in interconnect applications. Microelectron Eng 64:399–408
Awano Y, Sato S, Nihei M et al (2010) Carbon nanotubes for VLSI: interconnect and transistor applications. Proc IEEE 98:2015–2031
Rueckes T, Kim K, Joselevich E et al (2000) Carbon nanotube-based nonvolatile random access memory for molecular computing. Science 289:94–97
Xu W, Wu S, Li X et al (2016) High-efficiency large-area carbon nanotube-silicon solar cells. Adv Energy Mater 6:1600095
Nguyen MH, Bui HT, Pham VT et al (2016) Thermo-mechanical properties of carbon nanotubes and applications in thermal management. Adv Nat Sci Nanosci Nanotechnol 7:25017
Fu Y, Nabiollahi N, Wang T et al (2012) A complete carbon-nanotube-based on-chip cooling solution with very high heat dissipation capacity. Nanotechnology 23:045304
Ding Y, Alias H, Wen D, Williams RA (2006) Heat transfer of aqueous suspensions of carbon nanotubes (CNT nanofluids). Int J Heat Mass Transf 49:240–250
Hong H, Wright B, Wensel J et al (2007) Enhanced thermal conductivity by the magnetic field in heat transfer nanofluids containing carbon nanotube. Synth Met 157:437–440
Sahoo NG, Cheng HKF, Cai J et al (2009) Improvement of mechanical and thermal properties of carbon nanotube composites through nanotube functionalization and processing methods. Mater Chem Phys 117:313–320
Hu Z, Comeras J, Park H et al (2016) Physically unclonable cryptographic primitives using self-assembled carbon nanotubes. Nat Nanotechnol 11:559
Rojas W, McMorrow J, Geier M et al (2017) Solution-processed carbon nanotube true random number generator. Nano Lett 17:4976–4981
Yang Y, Ding L, Chen H et al (2018) Carbon nanotube network film-based ring oscillators with sub 10-ns propagation time and their applications in radio-frequency signal transmission. Nano Res 11:300–310
Son D, Koo JH, Song J-K et al (2015) Stretchable carbon nanotube charge-trap floating-gate memory and logic devices for wearable electronics. ACS Nano 9:5585–5593
Show Y, Nakashima T, Fukami Y (2013) Anticorrosion coating of carbon nanotube/polytetrafluoroethylene composite film on the stainless steel bipolar plate for proton exchange membrane fuel cells. J Nanomater 2013:1–7
Sachyani E, Layani M, Tibi G et al (2017) Enhanced movement of CNT-based actuators by a three-layered structure with controlled resistivity. Sens Actuators B 252:1071–1077
Sanchez Esqueda I, Yan X, Rutherglen C et al (2018) Aligned carbon nanotube synaptic transistors for large-scale neuromorphic computing. ACS Nano 12:7352–7361
Susantyoko R, Karam Z, Alkhoori S et al (2017) A surface-engineered tape-casting fabrication technique toward the commercialisation of freestanding carbon nanotube sheets. J Mater Chem A 5:19255–19266
Behabtu N, Young CC, Tsentalovich DE et al (2013) Strong, light, multifunctional fibers of carbon nanotubes with ultrahigh conductivity. Science 339:182–186
Ihsanullah (2019) Carbon nanotube membranes for water purification: developments, challenges, and prospects for the future. Sep Purif Technol 209:307–337
Current Intelligence Bulletin 65: Occupational exposure to carbon nanotubes and nanofibers (National Institute for Occupational Safety and Health), 2013
Eatemadi A, Daraee H, Karimkhanloo H et al (2014) Carbon nanotubes: properties, synthesis, purification, and medical applications. Nanoscale Res Lett 9:1–13
Razali M, Kim J, Attfield M et al (2015) Sustainable wastewater treatment and recycling in membrane manufacturing. Green Chem 17:5196–5205
Elnashaie SSE, Danafar F, Ahmadun F-R (2013) Sustainable world through sustainable materials and integrated biorefineries. Appl Petrochem Res 3:107–116
Acknowledgements
We thank Sahil Dawka for preliminary work related to the manuscript and the UBC bioimaging facility for SEM use.
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This work was funded in part (graduate student and equipment support) by the Natural Sciences and Engineering Research Council (NSERC).
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AV was the lead author and wrote most of the manuscript. EVA assisted with writing and editing parts of the manuscript. YC helped obtain and analyze some of the results presented in the manuscript. CP organized, wrote, edited and provided overall guidance on the manuscript. All authors read and approved the final manuscript.
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Venkataraman, A., Amadi, E.V., Chen, Y. et al. Carbon Nanotube Assembly and Integration for Applications. Nanoscale Res Lett 14, 220 (2019). https://doi.org/10.1186/s11671-019-3046-3
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DOI: https://doi.org/10.1186/s11671-019-3046-3