Chemistry:Elephant's toothpaste

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Short description: Foamy substance created by rapidly decomposing hydrogen peroxide (H2O2)

File:14. Слоновска паста за заби.webm

A teacher and a student doing the elephant's toothpaste experiment in a classroom setting.

Elephant's toothpaste is a foamy substance caused by the rapid decomposition of hydrogen peroxide (H
2
O
2
) using potassium iodide (KI) or yeast and warm water as a catalyst.[1] How rapidly the reaction proceeds will depend on the concentration of hydrogen peroxide.[2][3][4]

Because it requires only a small number of ingredients and makes a "volcano of foam", it is a popular experiment for children to perform in school or at parties.

Explanation

File:Elephant (1).ogg

Description

About 50 ml of concentrated (>12%)[5] hydrogen peroxide is first mixed with liquid soap or dishwashing detergent. Then, a catalyst, often around 10 ml potassium iodide solution or catalase from baker's yeast, is added to make the hydrogen peroxide decompose very quickly. Hydrogen peroxide breaks down into oxygen and water. As a small amount of hydrogen peroxide generates a large volume of oxygen, the oxygen quickly pushes out of the container.[6] The soapy water traps the oxygen, creating bubbles, and turns into foam.[6] About 5-10 drops of food coloring could also be added before the catalyst to dramatize the effect. How rapidly the reaction occurs will depend on the concentration of hydrogen peroxide used.[7]

Chemical explanation

This experiment shows the catalyzed decomposition of hydrogen peroxide. Hydrogen peroxide (H2O2) decomposes into water and oxygen gas, which is in the form of foam, but normally the reaction is too slow to be easily perceived or measured:[2]

[math]\ce{ 2H2O2 -> 2H2O + O2 ^ }[/math]

In normal conditions, this reaction takes place very slowly, therefore a catalyst is added to speed up the reaction, which will result in rapid formation of foam. The iodide ion from potassium iodide acts as a catalyst and speeds up the reaction while remaining chemically unchanged in the reaction process.[2][3][8] The iodide ion changes the mechanism by which the reaction occurs:

[math]\displaystyle{ \begin{array}{llllll} \ce{H2O2} &+\ \ce{I-} &\ce{-\gt H2O} &+\ \ce{IO-} \\ \ce{H2O2} &+\ \ce{IO-} &\ce{-\gt H2O} &+\ \ce{O2 ^} &+\ \ce{I-} \\ \hline \ce{2H2O2} & &\ce{-\gt 2H2O} &+\ \ce{O2 ^} & &\Delta_\mathrm{r}H^\circ = -196\text{ kJ/mol} \end{array} }[/math]

The reaction is exothermic; the foam produced is hot (about 75°C or 167°F).[specify][2][3] A glowing splint can be used to show that the gas produced is oxygen.[9] The rate of foam formation measured in volume per time unit has a positive correlation with the peroxide concentration (v/V%), which means that more foam will be generated per unit time when a more concentrated peroxide solution is used.[10]

Materials for the experiment

Variations

YouTube science entertainer Mark Rober has created a variation of the experiment, named "Devil's Toothpaste", which has a far more pronounced reaction than the version usually performed in classroom settings.[11][12] The ingredients to create the devils toothpaste reaction are the same as the regular elephants toothpaste reaction, the only difference being that 50% H2O2 instead of the usual 35%.[citation needed]

See also

References

  1. "Elephant Toothpaste". https://www.imaginationstationtoledo.org/educator/activities/elephant-toothpaste. 
  2. 2.0 2.1 2.2 2.3 "Elephant's Toothpaste". University of Utah Chemistry Demonstrations. University of Utah. http://www.chem.utah.edu/_documents/pdf/undergrad_program/elephants%20toothpaste.pdf. 
  3. 3.0 3.1 3.2 "Elephant's Toothpaste - Kid Version". Steve Spangler Science. http://www.stevespanglerscience.com/lab/experiments/elephants-toothpaste#sthash.aQZSJeLD.dpuf. 
  4. Dirren, Glen; Gilbert, George; Juergens, Frederick; Page, Philip; Ramette, Richard; Schreiner, Rodney; Scott, Earle; Testen, May et al. (1983). "Chemical Demonstrations". A Handbook for Teachers of Chemistry. 1 (1): 180–185. doi:10.1021/ed062pA31.2. Bibcode1985JChEd..62R..31K. 
  5. "Elephant's Toothpaste (slow motion)". Periodic Table of Videos. The University of Nottingham. Archived from the original on 2016-09-28. Retrieved 2016-09-14.
  6. 6.0 6.1 "The Great Elephant Toothpaste Experiment!". 2013-10-09. https://www.pbs.org/parents/adventures-in-learning/2013/10/the-great-elephant-toothpaste-experiment/. 
  7. "Elephant Toothpaste: A Hydrogen Peroxide Chemistry Experiment". http://www.using-hydrogen-peroxide.com/elephant-toothpaste.html. 
  8. Dirren, Glen; Gilbert, George; Juergens, Frederick; Page, Philip; Ramette, Richard; Schreiner, Rodney; Scott, Earle; Testen, May et al. (1983). "Chemical Demonstrations". A Handbook for Teachers of Chemistry. 1 (1): 180–185. doi:10.1021/ed062pA31.2. Bibcode1985JChEd..62R..31K. 
  9. "Catalytic Decomposition of H2O2 – Elephant's Toothpaste". https://ncsu.edu/project/chemistrydemos/Kinetics/Elephants%20Toothpaste.pdf. 
  10. Hernando, Franco; Laperuta, Santiago; Kuijl, Jeanine Van; Laurin, Nihuel; Sacks, Federico; Ciolino, Andrés (2017). "Elephant Toothpaste". Journal of Chemical Education 94 (7): 907–910. doi:10.1021/acs.jchemed.7b00040. 
  11. "NASA Engineer Sets Elephant Toothpaste Fountain World Record". https://nerdist.com/article/tallest-ever-elephant-toothpaste-fountain-world-record/. 
  12. "YouTuber Mark Rober throws birthday party for Rocky River boy with brain cancer". 22 September 2020. https://fox8.com/news/youtuber-mark-rober-throws-birthday-party-for-rocky-river-boy-with-brain-cancer/. 

External links