1. Carbon Nanotubes ECIV 303 Daniel Baker Nate Tipora Whitney Weston ECIV 303 Daniel Baker Nate Tipora Whitney Weston

2. Properties  Highest tensile strength of any material EVARRR!!!!  63 GPa compared to.4 GPa (structural steel ASTM A36)  1/50,000 th the width of a human hair  132,000,000:1 possible length to diameter ratio  Up to 18 cm in length  Made up of hexagonal structures that can be linked to form strands or sheets.  Highest tensile strength of any material EVARRR!!!!  63 GPa compared to.4 GPa (structural steel ASTM A36)  1/50,000 th the width of a human hair  132,000,000:1 possible length to diameter ratio  Up to 18 cm in length  Made up of hexagonal structures that can be linked to form strands or sheets.

4. Current Applications  Cement Based Foam Concrete Reinforced by Carbon Nanotubes  Increases foam concrete’s compressive strength by up to 70% making it comparable to conventional concrete at approximately 2800 psi  50% less dense than conventional concrete with an average density of under 70 lb/ft^3  Easy to pour as a slurry  Carbon nanotubes make up 0.05% of the mix by mass.  Reduce heat conductivity between 12-20%  Used in resins, which makes composite materials 20-30% stronger. (Chemically bond to epoxy)  Found in wind turbines, hunting arrows, and surfboards.  Cement Based Foam Concrete Reinforced by Carbon Nanotubes  Increases foam concrete’s compressive strength by up to 70% making it comparable to conventional concrete at approximately 2800 psi  50% less dense than conventional concrete with an average density of under 70 lb/ft^3  Easy to pour as a slurry  Carbon nanotubes make up 0.05% of the mix by mass.  Reduce heat conductivity between 12-20%  Used in resins, which makes composite materials 20-30% stronger. (Chemically bond to epoxy)  Found in wind turbines, hunting arrows, and surfboards.

5. Potential Applications  Water Purification  Removal of arsenic, fluoride, heavy metals, and toxic organic components  Super-bridges  May be used in bundles as cables for suspension bridges  Could increase the main span of a bridge by a factor of approximately three

6. SPACE ELEVATOR

7. References  Belluci, S. (19 January 2005). "Carbon nanotubes: physics and applications". Physica Status Solidi (c) 2 (1): 34–47. doi:10.1002/pssc.200460105doi10.1002/pssc.200460105  Wang, X.; Li, Q.; Xie, J.; Jin, Z.; Wang, J.; Li, Y.; Jiang, K.; Fan, S. (2009). "Fabrication of Ultralong and Electrically Uniform Single-Walled Carbon Nanotubes on Clean Substrates". Nano Letters 9 (9): 3137–3141. doi:10.1021/nl901260bdoi10.1021/nl901260b  Picture1-THE JOURNAL OF NUCLEAR MEDICINE  Picture2-2006-11-15 Original uploader was Booyabazooka at en.wikipediaBooyabazookaen.wikipedia  Carbon Nanotubes  http://en.wikipedia.org/wiki/Carbon_nanotube  Introduction to Nanotechnology  http://nanogloss.com/nanotubes/what-are-the-physical-properties-of-carbon-nanotubes/ http://nanogloss.com/nanotubes/what-are-the-physical-properties-of-carbon-nanotubes/  Belluci, S. (19 January 2005). "Carbon nanotubes: physics and applications". Physica Status Solidi (c) 2 (1): 34–47. doi:10.1002/pssc.200460105doi10.1002/pssc.200460105  Wang, X.; Li, Q.; Xie, J.; Jin, Z.; Wang, J.; Li, Y.; Jiang, K.; Fan, S. (2009). "Fabrication of Ultralong and Electrically Uniform Single-Walled Carbon Nanotubes on Clean Substrates". Nano Letters 9 (9): 3137–3141. doi:10.1021/nl901260bdoi10.1021/nl901260b  Picture1-THE JOURNAL OF NUCLEAR MEDICINE  Picture2-2006-11-15 Original uploader was Booyabazooka at en.wikipediaBooyabazookaen.wikipedia  Carbon Nanotubes  http://en.wikipedia.org/wiki/Carbon_nanotube  Introduction to Nanotechnology  http://nanogloss.com/nanotubes/what-are-the-physical-properties-of-carbon-nanotubes/ http://nanogloss.com/nanotubes/what-are-the-physical-properties-of-carbon-nanotubes/