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Nano

Nano. Slow-Releasing Nanoburrs From herbal tea. Honeybee's two compound eyes . Up Close With Your Tongue. Sugar. Single layer of graphene. Pollen. What's Measured Gets Managed . What do you measure ?. Common Unit Conversions used in Nanoscience. 1 m = 100 cm 1 m = 1,000 mm

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Nano

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  1. Nano

  2. Slow-Releasing Nanoburrs From herbal tea

  3. Honeybee's two compound eyes

  4. Up Close With Your Tongue

  5. Sugar

  6. Single layer of graphene

  7. Pollen

  8. What's Measured Gets Managed. What do you measure?

  9. Common Unit Conversions used in Nanoscience 1 m = 100 cm 1 m = 1,000 mm 1 m = 1,000,000 μm = 106μm 1 m = 1,000,000,000 nm = 109 nm 1 m = 10,000,000,000 Å = 1010Å 1 cm = 107 nm 1 cm = 108 Å 1 mm = 1,000 μm 1 μm = 1,000 nm 1 μm = 10,000 Å nm – measure atomic structure Å – measure light waves FNI 1B

  10. One nanometer = 3 silicon atoms in a row cm inches 1,000,000 nanometers 1 millimeter = 1,000,000 nanometers

  11. IBM logo made up of 35 atoms of xenon on nickel 17 nanometres long and was made with a scanning tunnelling microscope in 1986

  12. Spider’s Skin

  13. Human Hair with Lice

  14. The tree-like structures in this scanning electron microscope image of a cross section of a butterfly wing are on the undersides of the Morpho's wing scale ridges. These microribs reflect light to create iridescent colors. The Blue Morpho is common in Central and South America and known for its bright blue wings. However, these iridescent colors are created not by pigments in the wing tissues but instead by the way light interacts with nanometer-sized structures on the Morpho's wing scales. This effect is being studied as a model in the development of new fabrics, dye-free paints, and anti-counterfeit technologies for currency.

  15. Structure of butterfly wing

  16. Based on this discovery of butterflies wing structure, engineers are developing single sensors that are tailored to detect certain types of chemical agents or explosives. These sensors light up when they encounter threats.

  17. Small, smaller, "nano" data storage! Metallofullerene Model 80 carbon atoms (light blue) 3 dysprosium atoms (red) 1 nitrogen atom (dark blue)

  18. Small, smaller, "nano" transport of very small Nanotube

  19. T4 Bacteriophage - a virus

  20. Your Brain There are approximately 50,000,000 neurons per square centimeter (50X106 per cm3) Each cm3 neurons have axons that reach out to create 1 trillion synapse (1×1012) If each synapse can express 8 bits or 1 byte of information, than 1 cm3 contains 1 terabyte of data (1×1012) The human brain is roughly 1000 cm3 in size which means it can store about 1 petabyte of data (1×1015) That is about 1/3 as much data as stored in the entire internet … in one average human brain. So when will a computer the size of a brain match its capacity? By current rates of change it looks like we will be there between 2025 and 2030.

  21. Brain Cell – Soma and Dendrites

  22. Snail neuron grown on a chip that records the neuron’s activity

  23. Properties of a Material • A property describes how a material acts under certain conditions • Types of properties • Optical (e.g. color, transparency) • Electrical (e.g. conductivity) • Physical (e.g. hardness, melting point) • Chemical (e.g. reactivity, reaction rates) • Properties are usually measured by looking at large (~1023) aggregations of atoms or molecules Sources: http://www.bc.pitt.edu/prism/prism-logo.gif http://www.physics.umd.edu/lecdem/outreach/QOTW/pics/k3-06.gif

  24. Optical Properties Change: Color of Gold • Bulk gold appears yellow in color • Nanosized gold appears red in color • The particles are so small that electrons are not free to move about as in bulk gold • Because this movement is restricted, the particles react differently with light “Bulk” gold looks yellow 12 nanometer gold clusters of particles look red Sources: http://www.sharps-jewellers.co.uk/rings/images/bien-hccncsq5.jpg http://www.foresight.org/Conferences/MNT7/Abstracts/Levi/

  25. Electrical Properties Change: Conductivity of Nanotubes • Nanotubes- long, thin cylinders of carbon • 100 times stronger than steel, very flexible, • unique electrical properties • Their electrical properties change with diameter, “twist”, and number of walls • either conducting or semi-conducting in their electrical behavior Electric current varies by tube structure Multi-walled Source: http://www.weizmann.ac.il/chemphys/kral/nano2.jpg

  26. Physical Properties Change:Melting Point of a Substance • Melting Point (Microscopic Definition) • Temperature at which the atoms, ions, or molecules in a substance have enough energy to overcome the intermolecular forces that hold the them in a “fixed” position in a solid • Surface atoms require less energy to move because they are in contact with fewer atoms of the substance In contact with 3 atoms In contact with 7 atoms Sources: http://puffernet.tripod.com/thermometer.jpg and image adapted from http://serc.carleton.edu/usingdata/nasaimages/index4.html

  27. Physical Properties Example:Substance’s Melting Point II

  28. Size Dependant Properties Why do properties change?

  29. Scale Changes Everything • There are enormous scale differences in our universe! • At different scales • Different forces dominate • Different models better explain phenomena

  30. Scale Changes Everything II • Four important ways in which nanoscale materials may differ from macroscale materials • Gravitational forces become negligible and electromagnetic forces dominate • Quantum mechanics is the model used to describe motion and energy instead of the classical mechanics model • Greater surface to volume ratios • Random molecular motion becomes more important

  31. Dominance of Electromagnetic Forces • Because the mass of nanoscale objects is so small, gravity becomes negligible • Gravitational force is a function of mass and distance and is weak between (low-mass) nanosized particles • Electromagnetic force is a function of charge and distance is not affected by mass, so it can be very strong even when we have nanosized particles • The electromagnetic force between two protons is 1036 times stronger than the gravitational force! Sources: http://www.physics.hku.hk/~nature/CD/regular_e/lectures/images/chap04/newtonlaw.jpg http://www.antonine-education.co.uk/Physics_AS/Module_1/Topic_5/em_force.jpg

  32. Quantum Effects • Classical mechanical models that we use to understand matter at the macroscale break down for… • The very small (nanoscale) • The very fast (near the speed of light) • Quantum mechanics better describes phenomena that classical physics cannot, like… • The colors of nanogold • The probability (instead of certainty) of where an electron will be found Macrogold Nanogold Sources: http://www.phys.ufl.edu/~tschoy/photos/CherryBlossom/CherryBlossom.html http://www.nbi.dk/~pmhansen/gold_trap.ht; http://www.sharps-jewellers.co.uk/rings/images/bien-hccncsq5.jpg;

  33. Surface to Volume Ratio Increases • As surface to volume ratio increases • A greater amount of a substance comes in contact with surrounding material • This results in better catalysts, since a greater proportion ofthe material is exposed for potential reaction Source: http://www.uwgb.edu/dutchs/GRAPHIC0/GEOMORPH/SurfaceVol0.gif

  34. Random Molecular Motion is Significant • Tiny particles (like dust) move about randomly • At the macroscale, we barely see movement, or why it moves • At the nanoscale, the particle is moving wildly, batted about by smaller particles • Analogy • Imagine a huge (10 meter) balloon being batted about by the crowd in a stadium. From an airplane, you barely see movement or people hitting it; close up you see the balloon moving wildly. Source: http://www.ap.stmarys.ca/demos/content/thermodynamics/brownian_motion/rand_path.gif

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