# How Sweet It Is—How Much Sugar Is Really in That Soda?

 Difficulty Time Required Short (2-5 days) Prerequisites None Material Availability A precision hydrometer is required. See the Materials and Equipment list for details. Cost Average (\$50 - \$100) Safety Adult supervision is recommended. Use caution, as the hydrometer could break into sharp pieces of glass if dropped.

## Abstract

You know there is sugar in non-diet soda, but just how much sugar? Sure, you can look on the ingredients label, but how do food scientists actually measure the amount of sugar in a solution? They use a simple scientific device called a hydrometer. The hydrometer floats in the solution that is being tested, and the higher it floats, the more sugar there is! In this science fair project, you will use a precision hydrometer to measure the amount of sugar in soda.

## Objective

Use a hydrometer to measure the amount of sugar in soda.

## Credits

David B. Whyte, PhD, Science Buddies

### MLA Style

Science Buddies Staff. "How Sweet It Is—How Much Sugar Is Really in That Soda?" Science Buddies. Science Buddies, 24 Oct. 2014. Web. 25 May 2017 <http://www.sciencebuddies.org/science-fair-projects/project_ideas/FoodSci_p056.shtml>

### APA Style

Science Buddies Staff. (2014, October 24). How Sweet It Is—How Much Sugar Is Really in That Soda?. Retrieved May 25, 2017 from http://www.sciencebuddies.org/science-fair-projects/project_ideas/FoodSci_p056.shtml

## Share your story with Science Buddies!

Last edit date: 2014-10-24

## Introduction

Figure 1. A hydrometer immersed in liquid inside a graduated cylinder. The density of the liquid can be read from the scale inside the hydrometer at the surface of the water. (Wikipedia, 2009.)

How much salt is in seawater? How much blue dye is in that fruit drink? Or how much sugar is in your can of soda? Chemists have many ways to measure the concentration of various substances in solutions. To measure the amount of salt in seawater, for instance, they might measure how well the solution conducts electricity, since the higher the level of dissolved salt, the higher the electrical conductivity of the water. Or to measure how much blue dye is in a blue-colored solution, they might measure how much light is absorbed by the solution, since the more blue dye there is, the less light will pass through the solution. And one way to measure the amount of sugar in a solution is to determine its density (the mass per unit of volume). The higher the density, the higher the concentration of sugar. Pure water at room temperature has a mass of 1 gram (g) per 1 cubic centimeter (cm3), or a density of 1.0 g/cm3. For comparison, lead has a density of 11.4 g/cm 3. So if you had equal volumes of lead and water, the lead would weigh over 11 times as much as the water! Scientists have studied how the density of a solution changes as the amount of sugar increases. Based on this data, if you know the density of a sugar solution, you can look up the concentration of sugar. The density can be measured easily, using a hydrometer, shown to the right in Figure 1.

A hydrometer is made of glass and consists of a cylindrical stem and a bulb weighted with lead, or other heavy metal, to make it float upright. The hydrometer is gently lowered into the liquid to be tested until it floats freely. The point at which the surface of the liquid touches the stem of the hydrometer depends on the density of the solution. The hydrometer contains a paper scale inside the stem, so that the density can be read directly.

The operation of the hydrometer is based on Archimedes' principle, which states that a solid suspended in a liquid will be buoyed up by a force equal to the weight of the liquid displaced. In other words, the denser the solution, the higher up the hydrometer will float. The scale on the hydrometer goes from 0 to 70. This is the percent of sugar. So for water, the hydrometer sinks down to the region where the scale says "0" at the level of the liquid surface, since there is no sugar in water (the solution). In a 30-percent sugar solution (30 g of sugar in 100 g of solution), the hydrometer floats so the number 30 is at the surface of the solution. The food industry refers to the percent sugar as degrees Brix, (°Bx) so a 30-percent solution is 30 degrees Brix, or 30°Bx.

Sugar is a key ingredient in soda, and in many more of our favorite foods and drinks. It provides the sweetness that makes the soda so appealing, yet is also full of unnecessary calories. If you drink non-diet sodas, you know they are usually sweet, but do you know how sweet? How many spoonfuls of sugar are there in a single can of soda? In this food science fair project, you will use a hydrometer to determine the amount of sugar in your favorite soda. See if your experiments confirm the sugar content on the label!

## Terms and Concepts

• Solution
• Conduction
• Electricity
• Density
• Hydrometer
• Archimedes' principle
• Degrees Brix (°Bx)
• Standard solution
• Standard curve

### Questions

• Why do some businesses use hydrometers?
• How does a hydrometer work?
• What is the definition of solution?
• Can you explain Archimedes' principle in your own words?

## Bibliography

For help creating graphs, try this website:

## News Feed on This Topic

, ,
Note: A computerized matching algorithm suggests the above articles. It's not as smart as you are, and it may occasionally give humorous, ridiculous, or even annoying results! Learn more about the News Feed

## Materials and Equipment

A project kit containing most of the items needed for this science project is available for puchase from AquaPhoenix Education. Alternatively, you can gather the materials yourself using this shopping list:

• Hydrometer, 0–35° Bx, available at kitchen specialty stores and online from Amazon.com
• Measuring container, 2-liter (L)
• Non-diet soda, 2-L plastic bottle (1)
• Funnel; available at kitchen stores and online from Amazon.com
• Plastic bottles, 2-L, empty and with caps (6)
• Permanent marker
• Lab notebook
• Sugar (sucrose), pure, white, granulated (5 pounds)
• Kitchen scale, such as the Fast Weigh MS-500-BLK Digital Pocket Scale, 500 by 0.1 G, available from Amazon.com
• Tap water; distilled, de-ionized water is preferable, but for this procedure, tap water is fine.
• Graph paper

Disclaimer: Science Buddies occasionally provides information (such as part numbers, supplier names, and supplier weblinks) to assist our users in locating specialty items for individual projects. The information is provided solely as a convenience to our users. We do our best to make sure that part numbers and descriptions are accurate when first listed. However, since part numbers do change as items are obsoleted or improved, please send us an email if you run across any parts that are no longer available. We also do our best to make sure that any listed supplier provides prompt, courteous service. Science Buddies does participate in affiliate programs with Amazon.com, Carolina Biological, Jameco Electronics, and AquaPhoenix Education. Proceeds from the affiliate programs help support Science Buddies, a 501(c)(3) public charity. If you have any comments (positive or negative) related to purchases you've made for science fair projects from recommendations on our site, please let us know. Write to us at scibuddy@sciencebuddies.org.

## Experimental Procedure

Important Notes Before You Begin:

• The Brix scale actually measures the total dissolved solids. For soda, almost all of the dissolved solids are sugar, so the hydrometer reading reflects the percent sugar.
• The density change that occurs as more and more sugar is added to a solution depends on the temperature of the solution. The scale inside the hydrometer is for 20°C. For the purposes of this science fair project, you will assume the temperature is 20°C. If you do want to correct for the temperature, a table is provided with the hydrometer that shows you how.
• The procedure calls for using 2-L containers. The reason for using large bottles is that the hydrometer sinks up to 26 cm (10 inches) in the liquid. Other tall containers may be substituted as long as they can accomodate the hydrometer.

### Removing Carbon Dioxide from the Soda

1. The first step is to remove the carbon dioxide gas in the soda; otherwise, the bubbles from the carbonated drink will stick to the hydrometer and result in an inaccurate reading. Note: If the soda you are using is non-carbonated, skip this section.
2. Pour the soda out of its bottle and into the 2-L container.
3. Pour the soda back into the bottle, using the funnel if needed.
4. Repeat pouring back and forth five times, or until there are no more carbon dioxide bubbles being produced.
5. Pour the soda into the bottle.
6. Leave the lid off to let any remaining gas escape.
7. The contents should be at room temperature when you measure the sugar content.

### Creating the Sugar Solutions

1. The next step is to make a series of standard solutions. This is a series of solutions with increasing amounts of sugar. You will use the data for the density of these solutions to make a standard curve, which is a method to plot your data that will show the concentration of a substance.
2. Label the six empty 2-L containers with masking tape and the permanent marker, as follows:
1. 0% sugar
2. 5% sugar
3. 10% sugar
4. 15% sugar
5. 20% sugar
6. 25% sugar
3. Weigh out 100 grams (g) of sugar on the kitchen scale and put it into the bottle labeled "5% sugar." Use the funnel, if needed. This will be a 5 percent solution of sugar in water.
4. Weigh out the following amounts of sugar and pour it into the corresponding container:
1. 10% sugar bottle: 200 g of sugar
2. 15% sugar bottle: 300 g of sugar
3. 20% sugar bottle: 400 g of sugar
4. 25% sugar bottle: 500 g of sugar
5. Add water to each 2-L bottle (0%–25%) up to 2,000 mL (2 L).
1. Leave about 3 cm of air below the screw cap to allow for the volume increase when the hydrometer is immersed in the solutions.
2. All of the bottles should have the same volume when filled.
6. Put the caps on the bottles and shake to mix them, until all of the sugar is dissolved.

### Testing the Sugar Solutions

1. All of the solutions should be the same temperature before testing. Place the hydrometer in the "0% sugar" bottle or sediment tube. Immerse the hydrometer gently to avoid breaking the glass bulb.
1. Note: You need to be able to read the value on the hydrometer at the surface of the liquid. It is easiest to read the hydrometer when the water is slightly below the top of the bottle (involves some overflowing) or the surface of the water is below the cylinder where the cap screws on.
2. Experiment to see what works best for you.
3. Repeat the hydrometer reading for the 5%, 10%, 15%, 20%, and 25% sugar bottles.
1. Rinse and dry the hydrometer between readings.
5. Repeat steps 2–4 two more times. This will allow you to obtain more-accurate data.

### Testing the Soda

1. Place the hydrometer in the soda.
2. Record the value on the hydrometer scale in your lab notebook.
3. Remove the hydrometer, and rinse and dry it.
4. Repeat steps 1–3 for the soda two more times.

1. Graph the data for your standard curve, with the percent sugar on the x-axis and the hydrometer reading on the y-axis. You can use graph paper, or a website like Create a Graph. Graph each point separately, or use the average values.
2. Determine the sugar content of the soda by looking at the standard curve.
1. Find the value for the hydrometer reading on the y-axis, and then find the corresponding value for the sugar concentration on the x-axis.
3. Suggestion for your presentation: Put out a bowl with the amount of sugar you determined that is in the soda bottle, along with the soda bottle. See if people think it looks like more or less than they would have guessed.

## Variations

• One possible source of error for this science project is the fact that many sodas are made with fructose rather than sucrose (sugar). Modify the procedure to use corn syrup (fructose) rather than sugar. Do you get the same or different results? How do the hydrometer readings compare for the sugar solutions versus the corn syrup solutions?
• Test other sugar-containing drinks, such as grape juice, apple cider, sports drinks, etc.
• Add yeast to a sugar solution or natural juice (without preservatives) and use the hydrometer to track the decrease in sugar concentration due to fermentation.
• Make a standard curve for sodium chloride at 0, 1%, 2%, 3%, and 5% and use it to determine the amount of salt in seawater. You can purchase "instant sea water" at any pet store that has saltwater aquarium supplies. (This will be more challenging than the sugar experiment because of the lower concentrations.)
• Make your own hydrometer and compare its accuracy to the precision glass hydrometer.

## Share your story with Science Buddies!

The Ask an Expert Forum is intended to be a place where students can go to find answers to science questions that they have been unable to find using other resources. If you have specific questions about your science fair project or science fair, our team of volunteer scientists can help. Our Experts won't do the work for you, but they will make suggestions, offer guidance, and help you troubleshoot.

## If you like this project, you might enjoy exploring these related careers:

### Dietitian or Nutritionist

Ever wondered who plans the school lunch, food for patients at a hospital, or the meals for athletes at the Olympics? The answer is dietitians and nutritionists! A dietitian or nutritionist's job is to supervise the planning and preparation of meals to ensure that people—like students, patients, and athletes—are getting the right foods to make them as healthy and as strong as possible. Some dietitians and nutritionists also work to educate people about good food choices so they can cook and eat their own healthy meals. Read more

### Certified Diabetes Educator

Who does a diabetic turn to if they have questions or do not understand how to manage their disease? They consult a certified diabetes educator. These diabetes experts work with people who have diabetes (or pre-diabetes) so they know how to manage their condition. This can include educating people about how to measure and control their blood sugar levels, giving specific diet and exercise recommendations, and providing emotional support. Certified diabetes educators present health information in ways that their audience can relate to, and are sensitive to cultural differences. Read more

### Chemist

Everything in the environment, whether naturally occurring or of human design, is composed of chemicals. Chemists search for and use new knowledge about chemicals to develop new processes or products. Read more

### Food Scientist or Technologist

There is a fraction of the world's population that doesn't have enough to eat or doesn't have access to food that is nutritionally rich. Food scientists or technologists work to find new sources of food that have the right nutrition levels and that are safe for human consumption. In fact, our nation's food supply depends on food scientists and technologists that test and develop foods that meet and exceed government food safety standards. If you are interested in combining biology, chemistry, and the knowledge that you are helping people, then a career as a food scientist or technologist could be a great choice for you! Read more

## News Feed on This Topic

, ,
Note: A computerized matching algorithm suggests the above articles. It's not as smart as you are, and it may occasionally give humorous, ridiculous, or even annoying results! Learn more about the News Feed

## Looking for more science fun?

Try one of our science activities for quick, anytime science explorations. The perfect thing to liven up a rainy day, school vacation, or moment of boredom.