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clothes: waterproof tear-resistant textiles concrete: stop crack propagation [3] . polyethylene: increases the polymer's elastic modulus sports equipment: Stronger and lighter space elevator : !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!. high tensile strength fibers :
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clothes: waterproof tear-resistant textiles concrete: stop crack propagation[3]. polyethylene: increases the polymer's elastic modulus sports equipment: Stronger and lighter space elevator: !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! high tensile strengthfibers: ultrahigh-speed flywheels: buckypaper artificial muscles[6] buckypaper - heat sinkLCDfaraday cage chemical nanowires: conductive films: electric motor brushes: ultracapacitors:
light bulb filament: magnets: MWNTs coated with magnetite optical ignition: solar cells: photovoltaic superconductor: ultracapacitors: displays: transistor: loudspeaker: piezoelectric speakers in greeting air pollution filter: See also, Hydrogen Economy.[14] water filter: Mechanical oscillator: fastest known oscillators (> 50 GHz). nanotube membrane: slick surface: slicker than Teflon and waterproof.
clothes: waterproof tear-resistant textiles combat jackets: MIT is working on combat jackets that use carbon nanotubes as ultrastrong fibers and to monitor the condition of the wearer.[1] Cambridge University has developed the fibres and given a license to a company.[2] concrete: In concrete, they increase the tensile strength, and halt crack propagation[3]. polyethylene: Researchers have found that adding them to polyethylene increases the polymer's elastic modulus by 30%. sports equipment: Stronger and lighter tennis rackets, bike parts, golf balls, golf clubs, golf shaft and baseball bats. space elevator: This will be possible only if tensile strengths of more than about 70 GPa can be achieved.
high tensile strengthfibers: A large number of research groups have spun fibers of single wall carbon nanotubes embedded into a polymer. For example, fibers produced with polyvinyl alcohol required 600 J/g to break[4] In comparison, the bullet-resistant fiber Kevlar is 27–33 J/g. bridges: Carbon nanotubes may be able to replace steel in suspension bridges. ultrahigh-speed flywheels: The high strength/weight ratio enables very high speeds to be achieved. fire protection: covering material with a thin layer of buckypaper significantly improves its fire resistance due to the efficient reflection of heat by the dense, compact layer of carbon nanotubes or carbon fibers.[5].
artificial muscles[6] buckypaper - a thin sheet made from nanotubes that are 250 times stronger than steel and 10 times lighter that could be used as a heat sink for chipboards, a backlight for LCD screens or as a faraday cage to protect electrical devices/aeroplanes. chemical nanowires: Carbon nanotubes additionally can also be used to produce nanowires of other chemicals, such as gold or zinc oxide. These nanowires in turn can be used to cast nanotubes of other chemicals, such as gallium nitride. These can have very different properties from CNTs - for example, gallium nitride nanotubes are hydrophilic, while CNTs are hydrophobic, giving them possible uses in organic chemistry that CNTs could not be used for.
conductive films: A 2005 paper in Science notes that drawing transparent high strength swathes of SWNT is a functional production technique.[7] Additionally, Eikos Inc of Franklin, Massachusetts and Unidym Inc.[8] of Silicon Valley, California are developing transparent, electrically conductive films of carbon nanotubes to replace indium tin oxide (ITO) in LCDs, touch screens, and photovoltaic devices. Nanotube films show promise for use in displays for computers, cell phones, PDAs, and ATMs. electric motor brushes: Conductive carbon nanotubes have been used for several years in brushes for commercial electric motors. They replace traditional carbon black, which is mostly impure spherical carbon fullerenes. The nanotubes improve electrical and thermal conductivity because they stretch through the plastic matrix of the brush. This permits the carbon filler to be reduced from 30% down to 3.6%, so that more matrix is present in the brush.
This permits the carbon filler to be reduced from 30% down to 3.6%, so that more matrix is present in the brush. Nanotube composite motor brushes are better-lubricated (from the matrix), cooler-running (both from better lubrication and superior thermal conductivity), less brittle (more matrix, and fiber reinforcement), stronger and more accurately moldable (more matrix). Since brushes are a critical failure point in electric motors, and also don't need much material, they became economical before almost any other application. light bulb filament: alternative to tungsten filaments in incandescent lamps. magnets: MWNTs coated with magnetite optical ignition: A layer of 29% iron enriched SWNT is placed on top of a layer of explosive material such as PETN, and can be ignited with a regular camera flash.[9] solar cells: GE's carbon nanotube diode has a photovoltaic effect. Nanotubes can replace ITO in some solar cells to act as a transparent conductive film in solar cells to allow light to pass to the active layers and generate photocurrent. superconductor: Nanotubes have been shown to be superconducting at low temperatures.[10] ultracapacitors: MIT is researching the use of nanotubes bound to the charge plates of capacitors in order to dramatically increase the surface area and therefore energy storage ability.[11] displays: One use for nanotubes that has already been developed is as extremely fine electron guns, which could be used as miniature cathode ray tubes in thin high-brightness low-energy low-weight displays. This type of display would consist of a group of many tiny CRTs, each providing the electrons to hit the phosphor of one pixel, instead of having one giant CRT whose electrons are aimed using electric and magnetic fields. These displays are known as field emission displays (FEDs). transistor: developed at Delft, IBM, and NEC.
This permits the carbon filler to be reduced from 30% down to 3.6%, so that more matrix is present in the brush. Nanotube composite motor brushes are better-lubricated (from the matrix), cooler-running (both from better lubrication and superior thermal conductivity), less brittle (more matrix, and fiber reinforcement), stronger and more accurately moldable (more matrix). Since brushes are a critical failure point in electric motors, and also don't need much material, they became economical before almost any other application. light bulb filament: alternative to tungsten filaments in incandescent lamps.
magnets: MWNTs coated with magnetite optical ignition: A layer of 29% iron enriched SWNT is placed on top of a layer of explosive material such as PETN, and can be ignited with a regular camera flash.[9] solar cells: GE's carbon nanotube diode has a photovoltaic effect. Nanotubes can replace ITO in some solar cells to act as a transparent conductive film in solar cells to allow light to pass to the active layers and generate photocurrent. superconductor: Nanotubes have been shown to be superconducting at low temperatures.[10] ultracapacitors: MIT is researching the use of nanotubes bound to the charge plates of capacitors in order to dramatically increase the surface area and therefore energy storage ability.[11]
displays: One use for nanotubes that has already been developed is as extremely fine electron guns, which could be used as miniature cathode ray tubes in thin high-brightness low-energy low-weight displays. This type of display would consist of a group of many tiny CRTs, each providing the electrons to hit the phosphor of one pixel, instead of having one giant CRT whose electrons are aimed using electric and magnetic fields. These displays are known as field emission displays (FEDs). transistor: developed at Delft, IBM, and NEC.
loudspeaker: In November 2008, researchers at the Tsinghua-Foxconn Nanotechnology Research Centre in Beijing announced they had created loudspeakers from sheets of parallel carbon nanotubes, generating sound in a manner similar to how lightning produces thunder. Near-term commercial uses include replacing piezoelectric speakers in greeting cards.[12] [edit] Chemical air pollution filter: Future applications of nanotube membranes include filtering carbon dioxide from power plant emissions.[13]
biotech container: Nanotubes can be opened and filled with materials such as biological molecules, raising the possibility of applications in biotechnology. hydrogen storage: Research is currently being undertaken into the potential use of carbon nanotubes for hydrogen storage. They have the potential to store between 4.2 and 65% hydrogen by weight. This is an important area of research, since if they can be mass produced economically there is potential to contain the same quantity of energy as a 50L gasoline tank in 13.2L of nanotubes.
See also, Hydrogen Economy.[14] water filter: Recently nanotube membranes have been developed for use in filtration. This technique can purportedly reduce desalination costs by 75%. The tubes are so thin that small particles (like water molecules) can pass through them, while larger particles (such as the chloride ions in salt) are blocked. [edit] Mechanical This section does not cite any references or sources. Please help improve this article by adding citations to reliable sources (ideally, using inline citations). Unsourced material may be challenged and removed. (November 2008) oscillator: fastest known oscillators (> 50 GHz). nanotube membrane: Liquid flows up to five orders of magnitude faster than predicted by classical fluid dynamics. slick surface: slicker than Teflon and waterproof.
