Soda geyser

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A soda geyser is a physical reaction between a carbonated beverage, usually Diet Coke, and Mentos mints that causes the beverage to be expelled from its container. The candies catalyze the release of gas from the beverage, which creates an eruption that pushes most of the liquid up and out of the bottle.[1][2] Lee Marek and "Marek's Kid Scientists" were the first to publicly demonstrate the experiment on the Late Show with David Letterman in 1999.[3] Steve Spangler's televised demonstration of the eruption in 2005 became popular on YouTube,[4][5][6] launching a chain of several other Diet Coke and Mentos experiment viral videos.[7][8] Experiments carried out at altitudes ranging from below sea level in Death Valley to the summit of Pikes Peak have demonstrated that the reaction works better at higher elevations.[9][10][11]

History[edit]

In the 1910s,[citation needed] Wint-O-Green Life Savers were used to create soda geysers. The tubes of candies were threaded onto a pipe cleaner and dropped into the soft drink to create a geyser. At the end of the 1990s, the manufacturer of Wintergreen Lifesavers increased the size of the mints, and they no longer fit in the mouth of soda bottles. Science teachers found that Mentos candies had the same effect when dropped into a bottle of any carbonated soft drink.[1]

Lee Marek and "Marek's Kid Scientists" performed the Diet Coke and Mentos experiment on the Late Show with David Letterman in 1999.[3][12][13] In March 2002, Steve Spangler, a science educator, did the demonstration on KUSA-TV, an NBC affiliate, in Denver, Colorado.[14] The Diet Coke and Mentos geyser experiment became an internet sensation in September 2005. The experiment became a subject of the television show MythBusters in 2006.[13][15] Spangler signed a licensing agreement with Perfetti Van Melle, the maker of Mentos, after inventing an apparatus aimed to make it easier to drop the Mentos into the bottle and produce a large soda geyser.[16] Amazing Toys, Spangler's toy company, released the Geyser Tube toys in February 2007.[17] In October 2010, a Guinness World Record of 2,865 simultaneous geysers was set at an event organized by Perfetti Van Melle at the SM Mall of Asia Complex, in Manila, Philippines.[18] This record was afterward beaten in November 2014 by another event organized by Perfetti Van Melle and Chupa Chups in León, Guanajuato, Mexico, where 4,334 Mentos and soda fountains were set off simultaneously.[19]

Chemistry[edit]

SEM image of the surface of a Mentos candy

The eruption is caused by a physical reaction, rather than any chemical reaction. The addition of the Mentos leads to the rapid nucleation of carbon dioxide gas bubbles, degassing the solution:[2][20][21][22][23]

The conversion of dissolved carbon dioxide to gaseous carbon dioxide forms rapidly expanding gas bubbles in the soda, which pushes the beverage contents out of the container. Experimental measurements suggest that as many as 14 million bubbles are produced per liter of soda in this experiment.[20]

Carbonated sodas contain elevated levels of carbon dioxide under pressure. The solution becomes supersaturated with carbon dioxide when the bottle is opened, and the pressure is released. Under these conditions, carbon dioxide begins to degas from the solution, forming gas bubbles.

The activation energy for bubble nucleation (formation of bubbles) depends on where the bubble forms. It is very high for bubbles that form in the liquid itself (homogeneous nucleation), and much lower if bubble growth occurs within tiny bubbles trapped in some other surface (heterogeneous nucleation). Bubble nucleation and growth in carbonated beverages almost always occur by heterogeneous nucleation: diffusion of carbon dioxide into pre-existing bubbles within the beverage.[2][10][24][25] When dissolved gas diffuses into bubbles that already exist in a liquid, it is called Type IV bubble nucleation.[10] When the pressure is released from a soda bottle upon opening it, dissolved carbon dioxide can escape into any tiny bubble located within the beverage. These ready-made bubbles (which are nucleation sites) exist in things such as tiny fibers or non-wettable crevices on the sides of the bottle.[10][24][25] Because there usually are very few such pre-existing bubbles, the degassing process is slow. Mentos candies contain millions of cavities, roughly 1-3 μm in size,[26][10] that remain unwetted when added to a soda. Because of this, the addition of Mentos candies to a carbonated beverage provides enormous numbers of pre-existing bubbles into which dissolved carbon dioxide can escape. Thus, adding Mentos candies to a carbonated beverage introduces millions of nucleation sites into the drink, which allows for degassing that is rapid enough to support a jet of foam out of a bottle. While a Mentos candy contains millions of cavities, it is likely that only about 100,000 cavities actively nucleate bubbles on any single Mentos candy placed in a carbonated beverage.[20][26]

Pre-existing bubbles provide a way for the reaction to occur without requiring bubbles to form within the liquid itself (homogeneous nucleation). Because Type IV nucleation sites (such as found on Mentos) allow the reaction to proceed with substantially lower activation energy, Mentos candies can appropriately be considered a catalyst of the process.[10] As another example, dropping grains of salt or sand into the solution provides Type IV nucleation sites, lowers the activation energy compared to that of homogeneous nucleation, and increases the rate of carbon dioxide degassing.

The physical characteristics of Mentos (surface roughness) have the effect of drastically reducing the activation energy for carbon dioxide bubble formation so that the nucleation rate becomes exceedingly high. The activation energy for the release of carbon dioxide from Diet Coke by the addition of Mentos is 25 kJ mol−1.[23] The foaming is aided by the presence of food additives such as potassium benzoate, aspartame, sugars, citric acid, and flavorings in Diet Coke,[21] all of which influence the degree to which water can foam.[21][13][15][18] It has been claimed that gelatin and gum arabic in the Mentos candy enhance the fountain,[13][15][27] but experiments have shown that these candy additives do not affect the fountain.[2]

The nucleation reaction can start with any heterogeneous surface, such as rock salt, but Mentos have been found to work better than most.[1][15][18] Tonya Coffey, a physicist at Appalachian State University, suggested that aspartame in diet drinks lowers the surface tension in the water and causes a bigger reaction, but that caffeine does not accelerate the process. However, experiments have shown that some dissolved solids that increase the surface tension of water (such as sugars) also increase fountain heights.[21] Furthermore, it has also been demonstrated that addition of certain concentrations of alcohol (which lowers surface tension) to carbonated beverages decreases fountain heights.[26] These results suggest that additives serve to enhance geyser heights not by decreasing surface tension, but rather by some other mechanism. One possibility is that additives decrease bubble coalescence, which leads to smaller bubble sizes and greater foaming ability in the water.[28][29] Thus, the geyser reaction will still work even using sugared drinks, but diet is commonly used both for the sake of a larger geyser as well as to avoid having to clean up the stickier residue left by a sugared soda.[22][30]

Additional explanations for why diet sodas outperform regular sodas in this experiment have been proposed. For example, it has been suggested that the higher viscosity of regular sodas as compared to diet sodas could inhibit the formation of the fountain in regular sodas, leading to shorter fountains.[21][31] It has also been suggested that the more stable foams observed in diet sodas as compared to regular sodas could contribute to the taller geysers observed in diet sodas.[20]

  • A 2-litre (0.44 imp gal; 0.53 US gal) bottle of Diet Coke just after Mentos were dropped into it
    A 2-litre (0.44 imp gal; 0.53 US gal) bottle of Diet Coke just after Mentos were dropped into it
  • From left to right: action of five Mentos candies (per bottle) with Perrier, classic Coke, Sprite, and Diet Coke
    From left to right: action of five Mentos candies (per bottle) with Perrier, classic Coke, Sprite, and Diet Coke
  • Soda geyser
  • Diet Coke and Mentos eruption

Alternatives[edit]

While Diet Coke and Mentos are the most common way to make a soda geyser, they are not the only options. Many consider Diet Coke to be the optimal option. While Diet Coke has been studied and suggested that it has the strongest effect,[31] at least one other study has demonstrated that all diet sodas essentially work equally well within experimental error.[21] Nevertheless, any carbonated beverage will work.[32] As for the Mentos, many things work to nucleate carbonated beverages such as other candy, metal and ceramic spheres,[33] and even sand.[34][35]

See also[edit]

References[edit]

Wikimedia Commons has media related to Diet Coke and Mentos eruption.
  1. ^ a b c Spangler, Steve (2010). Naked Eggs and Flying Potatoes. Greenleaf Book Group Press.
  2. ^ a b c d Kuntzleman, Thomas S.; Annis, Jezrielle; Anderson, Hazel; Kenney, Joshua B.; Doctor, Ninad (2020). "Kinetic Modeling of and Effect of Candy Additives on the Candy–Cola Soda Geyser: Experiments for Elementary School Science through Physical Chemistry". Journal of Chemical Education. 97 (1): 283–288. Bibcode:2020JChEd..97..283K. doi:10.1021/acs.jchemed.9b00796. S2CID 209710757.
  3. ^ a b Suzanne Baker (May 23, 2014). "Naperville students integral to classic TV bits, but will the fun continue?". Naperville Sun. Archived from the original on October 6, 2014. Retrieved September 30, 2014.
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  8. ^ "About.com Chemistry page with instructions". Archived from the original on August 11, 2006. Retrieved August 4, 2006.
  9. ^ Delbert, Caroline (April 3, 2020). "Watch Scientists Conduct the Mentos and Diet Coke Experiment at 14,000 Feet". Popular Mechanics. Retrieved July 31, 2020.
  10. ^ a b c d e f Kuntzleman, Thomas S.; Johnson, Ryan (February 27, 2020). "Probing the Mechanism of Bubble Nucleation in and the Effect of Atmospheric Pressure on the Candy–Cola Soda Geyser". Journal of Chemical Education. 97 (4): 980–985. Bibcode:2020JChEd..97..980K. doi:10.1021/acs.jchemed.9b01177. ISSN 0021-9584. S2CID 214504768.
  11. ^ Kuntzleman, Thomas; Kenney, Joshua (2023). "Quantifying the Dynamics of the Candy Cola Soda Geyser Using a Simple and Inexpensive Protocol". Journal of Chemical Education.
  12. ^ Michelle Bova (February 19, 2007). "How Things Work: Mentos in Diet Coke". The Tartan. Retrieved September 30, 2014.
  13. ^ a b c d Tonya Shea Coffey. "Diet Coke and Mentos: What is really behind this physical reaction?" (PDF). Archived from the original (PDF) on October 28, 2014. Retrieved September 30, 2014.
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  17. ^ Greg Sandoval (February 13, 2007). "Toying with the Diet Coke and Mentos experiment". CNET. Retrieved September 30, 2014.
  18. ^ a b c Daven Hiskey (November 16, 2012). "Why Do Mentos and Diet Coke React?". Today I Found Out. Retrieved September 30, 2014.
  19. ^ "Most Mentos and soda fountains". Guinness World Records. Retrieved February 5, 2015.
  20. ^ a b c d Kuntzleman, Thomas S.; Imhoff, Amanda M. (October 30, 2021). "How Many Bubbles Are in the Foam Produced during the Candy-Cola Soda Geyser?". Journal of Chemical Education. 98 (12): 3915–3920. Bibcode:2021JChEd..98.3915K. doi:10.1021/acs.jchemed.1c01001. ISSN 0021-9584. S2CID 240328586.
  21. ^ a b c d e f New Demonstrations and New Insights on the Mechanism of the Candy-Cola Soda Geyser Thomas S. Kuntzleman, Laura S. Davenport, Victoria I. Cothran, Jacob T. Kuntzleman, and Dean J. Campbell Journal of Chemical Education. 94(5), 569-576. doi:10.1021/acs.jchemed.6b00862
  22. ^ a b Muir, Hazel (June 12, 2008). "Science of Mentos-Diet Coke explosions explained". New Scientist. Retrieved September 20, 2009.
  23. ^ a b Sims, Trevor P. T.; Kuntzleman, Thomas S. (October 11, 2016). "Kinetic Explorations of the Candy–Cola Soda Geyser". Journal of Chemical Education. 93 (10): 1809–1813. Bibcode:2016JChEd..93.1809S. doi:10.1021/acs.jchemed.6b00263. ISSN 0021-9584.
  24. ^ a b Jones, S. F.; Evans, G. M.; Galvin, K. P. (February 28, 1999). "Bubble nucleation from gas cavities — a review". Advances in Colloid and Interface Science. 80 (1): 27–50. doi:10.1016/S0001-8686(98)00074-8. ISSN 0001-8686.
  25. ^ a b Liger-Belair, Gérard (March 20, 2014). "How Many Bubbles in Your Glass of Bubbly?". The Journal of Physical Chemistry B. 118 (11): 3156–3163. doi:10.1021/jp500295e. ISSN 1520-6106. PMID 24571670.
  26. ^ a b c Kuntzleman, Thomas S.; Kuntzleman, Jacob T. (2021). "Ethanol as a Probe for the Mechanism of Bubble Nucleation in the Diet Coke and Mentos Experiment". Molecules. 26 (6): 1691. doi:10.3390/molecules26061691. PMC 8002754. PMID 33802982.
  27. ^ "MythBusters (2006 season)", Wikipedia, February 25, 2020, retrieved March 7, 2020
  28. ^ Katsir, Yael; Goldstein, Gal; Marmur, Abraham (May 1, 2015). "Bubble the wave or waive the bubble: Why seawater waves foam and freshwater waves do not?". Colloids and Interface Science Communications. 6: 9–12. doi:10.1016/j.colcom.2015.10.002.
  29. ^ Craig, V. S. J.; Ninham, B. W.; Pashley, R. M. (July 22, 1993). "Effect of electrolytes on bubble coalescence". Nature. 364 (6435): 317–319. Bibcode:1993Natur.364..317C. doi:10.1038/364317a0. S2CID 4345501.
  30. ^ Coffey, Tonya Shea (June 2008). "Diet Coke and Mentos: What is really behind this physical reaction?". American Journal of Physics. 76 (6): 551–557. Bibcode:2008AmJPh..76..551C. doi:10.1119/1.2888546.
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  32. ^ Helmenstine, Anne (January 10, 2019). "Does the Mentos and Soda Trick Work With Regular Coke?". thoughtco. Retrieved August 3, 2021.
  33. ^ Kuntzleman, Thomas S.; Nydegger, Michael W.; Shadley, Brooke; Doctor, Ninad; Campbell, Dean J. (August 14, 2018). "Tribonucleation: A New Mechanism for Generating the Soda Geyser". Journal of Chemical Education. 95 (8): 1345–1349. Bibcode:2018JChEd..95.1345K. doi:10.1021/acs.jchemed.8b00127. ISSN 0021-9584. S2CID 104069252.
  34. ^ MacLaren, Ruth (May 1, 2020). "The problem with the Coke & Mentos experiment that few people know about". Sciencedipity. Retrieved August 3, 2021.
  35. ^ "A Cheap Alternative to Mentos". NPR. August 1, 2006. Retrieved August 3, 2021.
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