A yellowish material is secreted by the ivy to aid it in clinging to surfaces. Nanoparticles within this material create the ability for the vine leaves to hold almost 2 million more times than its weight as well as provide the ability to absorb and disperse light due to their large surface-to-volume ratio. Sunscreens made with ivy nanoparticles would probably not need to be re-applied after swimming because the nanoparticles are more adhesive, and, while metal-based sunscreens give the skin a white tinge, the ivy nanoparticles are virtually invisible.
The study indicates that ivy nanoparticles are less toxic to mammalian cells than small-scale metal oxides, have a limited potential to penetrate through human skin, and are easily biodegradable.
Reference:
University of Tennessee at Knoxville (2010, July 19). Nanoparticles in English ivy may hold the key to making sunscreen safer and more effective. ScienceDaily. Retrieved July 22, 2010, from http://www.sciencedaily.com /releases/2010/07/100719162955.htm
Study Questions
- Write the formula for titanium dioxide and for zinc oxide.
- Give the oxidation state (number) for titanium and zinc in the compounds above.
- What is a nanoparticle?
- Explain the term surface-to-volume ratio.
- Why do nanoparticles have a large surface-to-volume ratio?
- How is the scattering of light affected by differences in surface-to-volume ratio?
- Why are titanium dioxide and zinc oxide the preferred metal oxides for use in sunscreens?
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