User:Eiad Jandali/Sandbox: Difference between revisions
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=Configuration= | =Configuration= | ||
As with many other allotropes of carbon, graphite utilizes sp2 carbon bonds, meaning that every atom of carbon is bonded with three other carbon atoms. Given a single sheet of carbon atoms, there are a variety of ways to manipulate the material to achieve slight variations on the cylindrical shape, length, and diameter. A set of vectors denoted by (n,m) represent how a given sheet of graphite is manipulated to achieve the tubular shape. For some properties of CNTs, it is these aspects that can alter how the nanotubes behave. [ | As with many other allotropes of carbon, graphite utilizes sp2 carbon bonds, meaning that every atom of carbon is bonded with three other carbon atoms. Given a single sheet of carbon atoms, there are a variety of ways to manipulate the material to achieve slight variations on the cylindrical shape, length, and diameter. A set of vectors denoted by (n,m) represent how a given sheet of graphite is manipulated to achieve the tubular shape. For some properties of CNTs, it is these aspects that can alter how the nanotubes behave. [http://books.google.com/books?hl=en&lr=&id=w_xpdFx0C4MC&oi=fnd&pg=PR5&dq=carbon+nanotubes+basics&ots=wDJLvqIHh_&sig=XufMBYMtw3V0sTEDos4xCUQl1aM#v=onepage&q=carbon%20nanotubes%20basics&f=false] | ||
Graphene, a single sheet of graphite, can be manipulated to form a single tube-like structure that is referred to as a single-walled carbon nanotubes. Alternatively it is possible to have a series of increasingly smaller nanotubes contained within one another that makes for parallel layers of graphene, which are known as carbon nanotubes. (Possibly insert picture displaying differences between single and multi-walled CNTs) | Graphene, a single sheet of graphite, can be manipulated to form a single tube-like structure that is referred to as a single-walled carbon nanotubes. Alternatively it is possible to have a series of increasingly smaller nanotubes contained within one another that makes for parallel layers of graphene, which are known as carbon nanotubes. (Possibly insert picture displaying differences between single and multi-walled CNTs) | ||
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Multi-walled carbon nanotubes are being investigated as a possible superconducting material. Due to their symmetry combined with cascaded nanotubes, superconductivity can be achieved by “linking” the different layers of the nanotubes. That being said, the temperature of operation for superconductivity is around 14K. While a temperature this low is impractical for mainstream uses, it is relatively higher than other superconducting materials. [6] | Multi-walled carbon nanotubes are being investigated as a possible superconducting material. Due to their symmetry combined with cascaded nanotubes, superconductivity can be achieved by “linking” the different layers of the nanotubes. That being said, the temperature of operation for superconductivity is around 14K. While a temperature this low is impractical for mainstream uses, it is relatively higher than other superconducting materials. [6] | ||
==Chemical== | ==Chemical== | ||
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==Electronics== | ==Electronics== | ||
Due to their versatile electrical properties, carbon nanotubes are being utilized and further explored as a material that can lead to highly improved electronics in many regards. | Due to their versatile electrical properties, carbon nanotubes are being utilized and further explored as a material that can lead to highly improved electronics in many regards. | ||
When functioning as a semi-conductor, carbon nanotubes can be applied towards developing field effect transistors (FETs) on the molecular scale. While transistors are feasible, the precision required to achieve a properly functioning FET is currently too high for mass production. [4] | When functioning as a semi-conductor, carbon nanotubes can be applied towards developing field effect transistors (FETs) on the molecular scale. While transistors are feasible, the precision required to achieve a properly functioning FET is currently too high for mass production. [4] Research is being conducted to explore the use of CNTs as memory units. While some success has been made in the field, CNTs tend to dissipate the charge after several hours. | ||
Research is being conducted to explore the use of CNTs as memory units. While some success has been made in the field, CNTs tend to dissipate the charge after several hours. | |||
Carbon nanotubes can be imbuedin a thin solid as a thin film. This film has many versatile characteristics of carbon nanotubes such as mechanical strength and high electrical conductiance. Nanofilaments typically high very high molecular surface areas but without the stregth or conductivity of CNTs. However, CNT films combine these many traits to form a more advanced hybrid of nanofilms and CNTs. In applications such as capacitances, where surface area increases the amout of energy stored, carbon nanotube films provide alternatives or possible to progress technology at the microscopic scale. In addition to energy storage, CNT films are expanding to implementation in a number of fields including electrodes in batteries, photovoltaic cells, and light-emitting diodes. | |||
Revision as of 22:17, 23 March 2011
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Carbon nanotubes (CNTs) are cylindrically shaped sheets of carbon, typically existing as the allotrope graphite. Carbon nanotubes are generally divided into two categories, single-walled and multi-walled, due to their differing properties and uses [1]. As a result of the strong carbon-to-carbon bonding, CNTs exhibit unique properties in material sciences and electronics that is the topic of recent on-going research. [2] Carbon nanotubes are currently being explored as an emerging technology in numerous fields such as electronics, optics, materials uses, and medicine. In addition to research regarding applications is the research being done to improve production of carbon nanotubes to include more precision and higher volumes of productions on a large scale. Development of “ultra-long” carbon nanotubes with extremely high length-to-diameter ratios is being researched due to their potential to greatly increase the applications of CNTs across their many fields of use.
Configuration
As with many other allotropes of carbon, graphite utilizes sp2 carbon bonds, meaning that every atom of carbon is bonded with three other carbon atoms. Given a single sheet of carbon atoms, there are a variety of ways to manipulate the material to achieve slight variations on the cylindrical shape, length, and diameter. A set of vectors denoted by (n,m) represent how a given sheet of graphite is manipulated to achieve the tubular shape. For some properties of CNTs, it is these aspects that can alter how the nanotubes behave. [2]
Graphene, a single sheet of graphite, can be manipulated to form a single tube-like structure that is referred to as a single-walled carbon nanotubes. Alternatively it is possible to have a series of increasingly smaller nanotubes contained within one another that makes for parallel layers of graphene, which are known as carbon nanotubes. (Possibly insert picture displaying differences between single and multi-walled CNTs)
Properties
Many of the unique properties commonly associated with carbon nanotubes can be attributed to their symmetrical and rounded form a well as the strength of the sp2 carbon-to-carbon bonds. Sp2 bonds are among the strongest atomics bonds in chemistry due to the configuration of valence electrons and the energy levels of carbon atoms. [3]
Mechanical
At their peak, carbon nanotubes are shown to have 5 times the stiffness of steel and 50 times the tensile strength. However, when placed under a sufficiently high strain, carbon nanotubes are shown to undergo a permanent breakdown at the molecular level.
Electrical
The uniformity of carbon bonds means carbon nanotubes have potential to have different electrical conductivities. Carbon Nanotubes are typically either semiconductors or conductors as conducive as metals such as copper. [2] The relationship between the array of carbon atoms (n, m) is the key factor in determining whether a nanotubes is conductor or semiconductor.
Multi-walled carbon nanotubes are being investigated as a possible superconducting material. Due to their symmetry combined with cascaded nanotubes, superconductivity can be achieved by “linking” the different layers of the nanotubes. That being said, the temperature of operation for superconductivity is around 14K. While a temperature this low is impractical for mainstream uses, it is relatively higher than other superconducting materials. [6]
Chemical
Multi-walled carbon nanotubes are more resistive to chemical breakdown that their single-walled counterparts.
Applications
Electronics
Due to their versatile electrical properties, carbon nanotubes are being utilized and further explored as a material that can lead to highly improved electronics in many regards. When functioning as a semi-conductor, carbon nanotubes can be applied towards developing field effect transistors (FETs) on the molecular scale. While transistors are feasible, the precision required to achieve a properly functioning FET is currently too high for mass production. [4] Research is being conducted to explore the use of CNTs as memory units. While some success has been made in the field, CNTs tend to dissipate the charge after several hours.
Carbon nanotubes can be imbuedin a thin solid as a thin film. This film has many versatile characteristics of carbon nanotubes such as mechanical strength and high electrical conductiance. Nanofilaments typically high very high molecular surface areas but without the stregth or conductivity of CNTs. However, CNT films combine these many traits to form a more advanced hybrid of nanofilms and CNTs. In applications such as capacitances, where surface area increases the amout of energy stored, carbon nanotube films provide alternatives or possible to progress technology at the microscopic scale. In addition to energy storage, CNT films are expanding to implementation in a number of fields including electrodes in batteries, photovoltaic cells, and light-emitting diodes.