Thursday, January 9, 2020

Whats the Science Behind Bubbles

Bubbles are beautiful, fun, and fascinating, but do you know what they are and how they work? Take a look at the science behind bubbles. What Is a Bubble? A bubble is a thin film of soapy water. Most of the bubbles that you see are filled with air, but you can make a bubble using other gasses, such as carbon dioxide. The film that makes the bubble has three layers. A thin layer of water is sandwiched between two layers of soap molecules. Each soap molecule is oriented so that its polar (hydrophilic) head faces the water, while its hydrophobic hydrocarbon tail extends away from the water layer. No matter what shape a bubble has initially, it will try to become a sphere. The sphere is the shape that minimizes ​the surface area of the structure, which makes it the shape that requires the least energy to achieve.​ What Happens When Bubbles Meet? When bubbles stack, do they remain spheres? No. When two bubbles meet, they will merge walls to minimize their surface area. If bubbles that are the same size meet, then the wall that separates them will be flat. If bubbles that are different sizes meet, then the smaller bubble will bulge into the large bubble. Bubbles meet to form walls at an angle of 120 degrees. If enough bubbles meet, the cells will form hexagons. You can see observe this structure by making prints of bubbles or by blowing bubbles between two clear plates. Ingredients in Bubble Solutions Though soap bubbles are traditionally made from (you guessed it) soap, most bubble solutions consist of detergent in water. Glycerin often is added as an ingredient. Detergents form bubbles in much the same way as soap, but detergents will form bubbles even in tap water, which contains ions that could prevent soap bubble formation. The soap contains a carboxylate group that reacts with calcium and magnesium ions, while detergents lack that functional group. Glycerin, C3H5(OH)3, extends the life of a bubble by forming weaker hydrogen bonds with water, slowing down its evaporation.

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