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Why Size Matters

This educational resource delves into the significance of size at the nanoscale level, detailing how properties and behaviors of materials change. It covers optical, electrical, physical, and chemical properties and the influence of surface-to-volume ratios. The text provides examples with gold and zinc oxide nanoparticles, illustrating how size impacts their properties. It also delves into the conductivity of nanotubes and the melting points of substances at microscopic levels. Key points such as the dominance of electromagnetic forces, quantum mechanics, and surface area ratios are discussed, emphasizing their importance in material research. Engaging in hands-on activities, students can explore these concepts with cards, blocks, and chemical reactions. Understanding the nuances of size at the nanoscale provides a foundational knowledge for exploring new materials. Source: Nanosense (2007). Retrieved from http://nanosense.org/activities/sizematters/properties/SM_PropSlides.ppt

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Why Size Matters

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  1. STEM ED/CHM Nanotechnology 2007 Why Size Matters Adapted from Nanosense http://nanosense.org/activities/sizematters/properties/SM_PropSlides.ppt

  2. Relative sizes (review) • Atomic nuclei ~ 10-15 meters = 10-6 nanometers • Atoms ~ 10-10 meters = 0.1 nanometers • Nanoscale ~ 1 to 100 nanometers ~ 10 to 1000 atoms • Everyday world ~ 1 meter = 109 nanometers

  3. The Basic Physics • At the everyday scale, Newton’s laws (F=ma, etc.) work fine • At the atomic and molecular level, quantum mechanics is needed to describe phenomena and properties • Discrete energy levels, tunneling • Nanomaterials are in a borderline region where either or both approaches may be appropriate

  4. The Basic Forces • Strong Nuclear Force – huge, hold nuclei together; act only at nuclear distances, 10-6 nm • Weak Nuclear Force – small, responsible for nuclear beta decay, act only at nuclear distances, 10-6 nm • Electric and Magnetic – dominant at atomic and nanotech scales; 1039× gravitational forces; long ranged, 1/r2 • Gravitational – long ranged, 1/r2; dominant at everyday world scale, since most objects lack a substantial net electrical charge

  5. Properties of a Material • Types of properties • Optical (e.g. color, transparency) • Electrical (e.g. conductivity) • Physical (e.g. hardness, melting point, diffusion rate) • Chemical (e.g. reactivity, reaction rates) • Properties are usually measured by looking at large (~1023) aggregations of atoms or molecules

  6. 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 12 nanometer gold particles look red “Bulk” gold looks yellow Sources: http://www.sharps-jewellers.co.uk/rings/images/bien-hccncsq5.jpg http://www.foresight.org/Conferences/MNT7/Abstracts/Levi/

  7. Optical Properties Example: Zinc Oxide (ZnO) • Large ZnO particles • Block UV light • Scatter visible light • Appear white • Nanosized ZnO particles • Block UV light • So small compared to the wavelength of visible light that they don’t scatter it • Appear clear • Application to sunscreen Nanoscale ZnO sunscreen is clear “Traditional” ZnO sunscreen is white Zinc oxide nanoparticles Sources: http://www.apt powders.com/images/zno/im_zinc_oxide_particles.jpg http://www.abc.net.au/science/news/stories/s1165709.htm http://www.4girls.gov/body/sunscreen.jpg

  8. Electrical Properties Example: Conductivity of Nanotubes • Nanotubes are long, thin cylinders of carbon • They are 100 times stronger than steel, very flexible, and have unique electrical properties • Their electrical properties change with diameter, “twist”, and number of walls • They can be 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

  9. 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

  10. A flower or a person at the edge of a crowd has fewer neighbors than one in the middle People at the edge can move more easily

  11. Surface to Volume Ratio Experiments • As a sample is made larger, a smaller fraction of the atoms (or molecules) are on the surface • Atoms on the surface have fewer neighbors than those on the interior • Students at the edge of the classroom have fewer neighbors than those in the center • Explore this with two activities – cards, blocks • Only atoms on the surface can interact with another material and take part in a chemical reaction • Explore this with Alka Seltzer tablets and powder

  12. What Does This All Mean? • Key factors for understanding nanoscale-related properties • Dominance of electromagnetic forces • Importance of quantum mechanical models • Higher surface area to volume ratio • Random (Brownian) motion • It is important to understand these four factors when researching new materials and properties

  13. Activities • Each table has one deck of cards, one bag of blocks, and 2 Alka Seltzer setups • 2 write-ups per team • Explore the effects of increasing size with the cards or the blocks • Swap with the other group at your table • Do the Alka- Seltzer experiment to see the effect of particle size on chemical processes

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