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Nanotechnology Basics (HS)

Nanotechnology Basics (HS). David T. Shaw State University of New York at Buffalo. What is Nanotechnology?. WHAT DOES NANOTECHNOLOGY MEAN TO YOU?. 3. What is Nanotecnology?. The study of objects and phenomena at a very small scale, roughly 1 to 100 nanometers (nm)

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Nanotechnology Basics (HS)

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  1. Nanotechnology Basics (HS) David T. Shaw State University of New York at Buffalo

  2. What is Nanotechnology? WHAT DOES NANOTECHNOLOGY MEAN TO YOU?

  3. 3 What is Nanotecnology? • The study of objects and phenomena at a very small scale, roughly 1 to 100 nanometers (nm) • 10 hydrogen atoms lined up measure about 1 nm • A grain of sand is 1 million nm, or 1 millimeter, wide • What’s interesting about the nanoscale? • Nanosized particles exhibit different properties than larger particles of the same substance • Studying phenomena at this scale will… • Change our understanding of matter • Lead to new questions and answers in many areas, like health care, energy, technology

  4. How Small is Nanometer? 1 nm = 10-9 meter

  5. How Small is Nanometer?

  6. What’s So Special About Nano? • Using new scientific tools, we have found that nano- sized particles of a given substance exhibit different properties than larger particles of the same substance • As we study these materials at the nanoscale, we are • Learning more about the nature of matter • Developing new theories • Learning how to manipulate their properties to develop new products and technologies

  7. Painting On Solar Cells • Nano solar cells mixed in plastic could be painted on buses, roofs, clothing • Solar becomes a cheap energy alternative! Inorganic nanorods embedded in semiconducting polymer -- sandwiched between two electrodes http://www.berkeley.edu/news/media/releases/2002/03/28_solar.html

  8. Natural chains of magnetic nano-crystals in bacteria Dunin-Borkowski Science (98) History of Nanotechnology Some have argued that nanoscience started billions year ago, whenthe first living cells emerge. Cells house nanoscale biomachines perform such tasks as manipulating genetic materials and supplying energy.

  9. “There’s Plenty of Room at the Bottom” Most, however, consider Richard Feynman’s famed talk in1959 as a historical moment for nanoscale science and technology • The accuracy of Feynman’s vision is breath-taking. A few of his predictions include: • electron and ion beam fabrication, • molecular beam epitaxy, • nanoimprint lithography, • scanning tunneling microscopy, • single electron transistors, • spin electronics, and • nanoelectromechanical systems (NEMS). • To read the entire Feynman’s classic paper, please Click

  10. 00 Chemistry 96 Chemistry 56 Physics 86 Physics 97 chemistry Genesis of Nanotechnology (Mitre 96)

  11. New Tools As tools change, what we can see and do changes

  12. Using Light to See • The naked eye can see to about 20 microns • A human hair is about 50-100 microns thick • Light microscopes let us see to about 1 micron • Bounce light off of surfaces to create images to see red blood cells (400x) Light microscope (magnification up to 1000x) Sources: http://www.cambridge.edu.au/education/PracticeITBook2/Microscope.jpg http://news.bbc.co.uk/olmedia/760000/images/_764022_red_blood_cells300.jpg

  13. Using Electrons to See • Scanningelectron microscopes, invented in the 1930s, let us see down to about 10 nanometers • Bounce electrons off of surfaces to create images • Higher resolution due to small size of electrons (4000x) Greater resolution to see things like blood cells in greater detail Sources: http://www.biotech.iastate.edu/facilities/BMF/images/SEMFaye1.jpg http://cgee.hamline.edu/see/questions/dp_cycles/cycles_bloodcells_bw.jpg

  14. Touching the Surface • Scanning probe microscopes, develop-ed in the 1980s, give us a new way to “see” at the nanoscale • We can now see really small things, like atoms, and move them too! This is about how big atoms are compared with the tip of the microscope Source: Scientific American, Sept. 2001

  15. Yoo et al, Science (97) Images of movement of electrons and holes through a semi-conductor substrate Tools of Nanotechnology Development of STM-related techniques greatly accelerates the progress of nanotechnology Bright spotselectrons, dark spots holes.

  16. IBM IBM Li, PRL(02) Omicron coronene STM Art Gallery

  17. How Do Properties of Nanostructures Change? • Properties of a substance depend on: • Size of the aggregation of particles • Surface to volume ratio • Also, at the nanoscale, some properties such as boiling temperature do not apply • Vapor pressure becomes less and less meaningful when you have smaller and smaller numbers of particles • When you have 50 molecules there are no bubbles!

  18. Size-Dependent Properties • Properties of a material • Describe how the material acts under certain conditions • Are often measured by looking at large (~1023) aggregation of atoms or molecules • Types of properties • Optical (e.g. color, transparency) • Electrical (e.g. conductivity) • Physical (e.g. hardness, boiling point) • Chemical (e.g. reactivity, reaction rates) Sources: http://www.bc.pitt.edu/prism/prism-logo.gif http://www.physics.umd.edu/lecdem/outreach/QOTW/pics/k3-06.gif

  19. Optical Properties Example: 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 particles look red Sources: http://www.sharps-jewellers.co.uk/rings/images/bien-hccncsq5.jpg http://www.foresight.org/Conferences/MNT7/Abstracts/Levi/

  20. Why Do Properties Change? • Four important ways in which nanoscale materials may differ from macro scale materials • Gravitational forces become negligible and electromagnetic forces begin to dominate • Quantum mechanics is used to describe motion and energy instead of classical mechanics • Greater surface to volume ratios • Random molecular motion becomes more important

  21. Dominance of Electromagnetic Forces • Because the mass of nanoscale objects is so small, gravity becomes negligible • Gravitational force is a function of mass and is weak between nanosized particles • Electromagnetic force is not affected by mass, so it can be very strong even when we have nanosized particles • The electromagnetic force is much more stronger than gravitational force at nanoscale

  22. Quantum Mechanical Model Needed • Classical mechanical models explain phenomena well at the macro scale level, but break down at the nano- scale level • Four phenomena that quantum mechanical models can explain (but classical mechanical models cannot) • Discreteness of energy • The wave-particle duality of light and matter • Quantum tunneling • Uncertainty of measurement

  23. Surface to Volume Ratio Increases • As surface to volume ratio increases • A greater amount of a substance comes in contact with surround-ing 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

  24. Random Molecular Motion is Significant • Random motion at the macro scale • Small compared the size of the substance • We can barely detect motion of dust particles on the surface of water • Random motion at the the nanoscale • Large when compared to the size of the substance • The molecules that make up the dust particle are moving wildly Source: http://galileo.phys.virginia.edu/classes/109N/ more_stuff/Applets/brownian/brownian.html

  25. Potential Impact of Nanotechnology • How might new innovations change our lives? • Materials: stain-resistant clothing • Environment: clean energy, clean air • Technology: better data storage and computation • Heathcare: chemical and biological sensors, drugs and delivery devices Thin layers of gold are used in tiny medical devices Possible entry point for nanomedical device Carbon nanotubes can do many things!

  26. A DVD That Could Hold a Million Movies • New nanomedia could result in a million times greater storage density New nanomedia: Gold self-assembles into strips on silicon (scale is nanometers) Current CD and DVD media (scale is microns) Source: http://uw.physics.wisc.edu/~himpsel/nano.html

  27. Building Smaller Devices and Chips • Nanolithography to create tiny patterns • Lay down “ink” atom by atom Transporting molecules to a surface by dip-pen nanolithography Mona Lisa, 8 microns tall, created by AFM nanolithography Re: http://www.ntmdt.ru/SPM-Techniques/Principles/Lithographies/AFM_Oxidation_Lithography_mode37.html http://www.chem.northwestern.edu/~mkngrp/dpn.htm

  28. Nerve Tissue Talking to Computers • Neuro-electronic networks interface nerve cells with semiconductors • Possible applications in brain research, neurocomputation, prosthetics, biosensors Snail neuron grown on a chip that records the neuron’s activity Source: http://www.biochem.mpg.de/mnphys/publications/05voefro/abstract.html

  29. Detecting Diseases Earlier Cancer in Color

  30. Growing Tissue to Repair Hearts • Growing cardiac muscle tissue is an area of current research • Grown in the lab now, but the fibers grow in random directions • With the help of nanofiber filaments, it grows in an orderly way • Could be used to replace worn out or damaged heart tissue Cardiac tissue grown with the help of nanofiber filaments Source: http://www.washington.edu/admin/finmgmt/annrpt/mcdevitt.htm

  31. Preventing Viruses from Infecting Us • The proteins on viruses bind to our body cells • Could cover these proteins with nanocoatings • Stop them from recognizing and binding to our cells • We would never get the flu! • A protein recognition system has been developed Influenza virus: Note proteins on outside that bind to cells Gold tethered to the protein shell of a virus Sources: http://www.zephyr.dti.ne.jp/~john8tam/main/Library/influenza_site/influenza_virus.jpg http://pubs.acs.org/cen/topstory/8005/8005notw2.html

  32. Making Repairs to the Body • Nanorobots are decades away, but could… • Break apart kidney stones, clear plaque from blood vessels, ferry drugs to tumor cells Source: http://www.genomenewsnetwork.org/articles/2004/08/19/nanorobots.php

  33. Summary • An emerging, interdisciplinary Science and technology nano- scale, integrating chemistry, physics, biology, and earth science with technology • The power to collect data and manipulate particles at nanoscale will lead to • New areas of research and technology design • Better understanding of matter and interactions • New ways to tackle important problems in healthcare, energy, environment, and technology • A few practical applications now, but most are years or decades away

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