The operational window of carbon nanotube electrical wires treated with strong acids and oxidants

Conventional metal wires suffer from a significant degradation or complete failure in their electrical performance, when subjected to harsh oxidizing environments, however wires constructed from Carbon Nanotubes (CNTs) have been found to actually improve in their electrical performance when subjected to these environments. These opposing reactions may provide new and interesting applications for CNT wires. Yet, before attempting to move to any real-world harsh environment applications, for the CNT wires, it is essential that this area of their operation be thoroughly examined. To investigate this, CNT wires were treated with multiple combinations of the strongest acids and halogens. The wires were then subjected to conductivity measurements, current carrying capacity tests, as well as Raman, microscopy and thermogravimetric analysis to enable the identification of both the limits of oxidative conductivity boosting and the onset of physical damage to the wires. These experiments have led to two main conclusions. Firstly, that CNT wires may operate effectively in harsh oxidizing environments where metal wires would easily fail and secondly, that the highest conductivity increase of the CNT wires can be achieved through a process of annealing, acetone and HCl purification followed by either H2O2 and HClO4 or Br2 treatment

Aligned carbon nanotube–epoxy composites: the effect of nanotube organization on strength, stiffness, and toughness

10.1007/s10853-016-0228-6Journal of Materials Science512210005-1002

Electrical properties of carbon nanotube based fibers and their future use in electrical wiring

The production of continuous fibers made purely of carbon nanotubes has paved the way for new macro-scale applications which utilize the superior properties of individual carbon nanotubes. These wire-like macroscopic assemblies of carbon nanotubes were recognized to have a potential to be used in electrical wiring. Carbon nanotube wiring may be extremely light and mechanically stronger and more efficient in transferring high frequency signals than any conventional conducting material, being cost-effective simultaneously. However, transfer of the unique properties of individual CNTs to the macro-scale proves to be quite challenging. This Feature Article gives an overview of the potential of using carbon nanotube fibers as next generation wiring, state of the art developments in this field, and goals to be achieved before carbon nanotubes may be transformed into competitive products. Carbon nanotubes, with their unique properties, could make electrical conductors of unprecedented performance, which could revolutionize energy transport globally. Is it feasible to produce macroscopic conductors from nanoscale structures? This Feature Article presents both the most recent results of a highly promising research program in this area and the key challenges that need to be overcome. © 2014 The Authors. Published by WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

Low Temperature Electrical Transport in Modified Carbon Nanotube Fibres

Carbon nanotube fibres are a new class of materials highly promising for many electrical/electronic applications. The range of applications could be extended through the modification of their electrical transport properties by inclusions of foreign materials. However, the changes in electrical transport are often difficult to assess. Here, we propose that the analysis of resistance–temperature dependencies of modified fibres supported by a recently developed theoretical model may aid research in this area and accelerate real life applications of the fibres

Influence of Atmospheric Water Vapour on Electrical Performance of Carbon Nanotube Fibres

Carbon nanotube assemblies are expected to find application in many areas of technology. Therefore, it is of paramount importance to understand and predict their performance in different ambient conditions. Here, we explore the influence of air exposure on the electrical conduction in carbon nanotube fibres and films produced via floating catalyst chemical vapour deposition. We recognise that on top of the previously well-explored oxygen doping effect these macroscopic materials are also significantly affected by humidity. The adsorption of water vapour causes an increase in the weight of the assemblies, increase in electrical conductivity at room temperature or changes in the resistance-temperature dependence at low temperatures. It is suggested that the water vapour is mainly adsorbed by the standard clustering mechanisms observed in other carbon materials, but the mechanisms responsible for the improvement in electrical performance are much more debatable. We present a strong indication that the carbon nanotubes are neither n-doped nor p-doped by water molecules and provide further discussion on the potential role of water in the electrical transport of carbon nanotube assemblies

Influence of Atmospheric Water Vapour on Electrical Performance of Carbon Nanotube Fibres

Carbon nanotube assemblies are expected to find application in many areas of technology. Therefore, it is of paramount importance to understand and predict their performance in different ambient conditions. Here, we explore the influence of air exposure on the electrical conduction in carbon nanotube fibres and films produced via floating catalyst chemical vapour deposition. We recognise that on top of the previously well-explored oxygen doping effect these macroscopic materials are also significantly affected by humidity. The adsorption of water vapour causes an increase in the weight of the assemblies, increase in electrical conductivity at room temperature or changes in the resistance-temperature dependence at low temperatures. It is suggested that the water vapour is mainly adsorbed by the standard clustering mechanisms observed in other carbon materials, but the mechanisms responsible for the improvement in electrical performance are much more debatable. We present a strong indication that the carbon nanotubes are neither n-doped nor p-doped by water molecules and provide further discussion on the potential role of water in the electrical transport of carbon nanotube assemblies