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# Rubbing Up Against Static Electricity

 Difficulty Time Required Very Short (≤ 1 day) Prerequisites None Material Availability Readily available Cost Very Low (under \$20) Safety No issues

## Abstract

A tried and true balloon activity is to rub a balloon on your head to make your hair stand up. How does the rubbing build up static electricity? Do this experiment to see if the number of rubs makes a difference.

## Objective

Test if the number of rubs of wool on a balloon increases or decreases how long the static charge will last.

## Credits

Sara Agee, Ph.D., Science Buddies

### MLA Style

Science Buddies Staff. "Rubbing Up Against Static Electricity" Science Buddies. Science Buddies, 4 May 2015. Web. 29 Apr. 2017 <http://www.sciencebuddies.org/science-fair-projects/project_ideas/Elec_p017.shtml?from=Blog>

### APA Style

Science Buddies Staff. (2015, May 4). Rubbing Up Against Static Electricity. Retrieved April 29, 2017 from http://www.sciencebuddies.org/science-fair-projects/project_ideas/Elec_p017.shtml?from=Blog

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Last edit date: 2015-05-04

## Introduction

Static electricity is the build-up of electrical charge in an object. Sometimes static electricity can suddenly discharge, like when a bolt of lightning flashes through the sky. Other times, static electricity can cause objects to cling to each other, like socks fresh out of the dryer. The static cling is an attraction between two objects with different charges, positive (+) and negative (–).

Figure 1. Static electricity makes your hair stand up! (NASA, 2004)

In this experiment you will test if the number of rubs can change how long the static charge will last by rubbing a balloon with wool and timing how long it will cling to a wall. Wool is a material that readily donates its electrons, so when you rub the balloon with it it will donate its electrons to the surface of the balloon, giving part of the balloon a negative charge. The wall should normally have a neutral charge, but the charges within it can rearrange so that a positively charged area is interacting with the negatively charged balloon, causing the balloon to stick to it. By doing this experiment you can investigate how effective rubbing wool against a balloon is at creating static electricity and a static charge.

## Terms and Concepts

• Static electricity
• Charges
• Electrons
• Static charge
• Attraction

### Questions

• How does friction produce static electricity?
• How is static electricity related to charge?
• How can you measure static electricity?

## Bibliography

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## Materials and Equipment

• Balloons (at least 3). Smaller balloons, like water balloons, may work better in humid environments, but you will still blow the balloons up with air.
• Woolly sweater, scarf, or blanket
• Stopwatch
• Lab notebook

## Experimental Procedure

1. For this experiment, you will need a data table for your results. You will need one data table for each trial, so make at least three data tables for doing at least three separate trials. You can use a data table like Table 1.
 Number of Rubs Stays on Wall? (Y/N) Time on Wall (seconds) 1 2 3 ...
Table 1. You can use a data table like this one to write down your results.
1. Blow up the balloon and tie off the end.
2. Rub the balloon on the scarf once, in one direction.
3. Hold the balloon up on the wall, start the stop watch and release. Does it stay on the wall? If not, stop your stop watch and write "0 seconds" in your data table.
4. Touch the balloon to a metal object. This should discharge any extra electrons into the metal.
5. Repeat steps 3 to 5, increasing the number of rubs each time until the balloon sticks to the wall. When you increase the number of rubs do not rub the balloon back and forth, but instead always rub the balloon in the same direction each time.
6. When the balloon does stick to the wall, keep the stop watch going until the balloon falls off of the wall. When it does, stop the stop watch and write the time in the data table next to the matching number of rubs.
7. Repeat step 7, increasing the number of rubs each time and recording the amount of time the balloon sticks to the wall with the stop watch. Write the results in the data table each time. You can continue increasing the number of rubs until you have several data points for the balloon sticking to the wall.
8. Make a graph of your results. You can make your graph by hand or you could use a program like Create a Graph to make it on a computer and print it out. A line graph is the best type of graph for this experiment. Make a scale on the left side of the graph (Y-axis) for the time in seconds, and a scale on the bottom of the graph (X-axis) for the number of robots. For each point of data, make a dot where the number of rubs and the time in seconds intersect.
9. Analyze your results. Does your data make a line? Does the line go up or down? Does the line level off at some point, or keep going? Does the time the balloon stays on the wall increase or decrease with the number of rubs?
10. Repeat steps 2–10 at least two more times so you have done a total of at least three trials total. Does the data for each trial match with the previous trials?

## Variations

• Does rubbing in one direction give a different result than rubbing back and forth? Try a different experiment comparing the same number of rubs in one direction compared to back and forth. Does one stay up on the wall longer than the other?
• Static electricity is not good when it gets in your clothes! How do dryer sheets work? Try an experiment rubbing the balloon with a dryer sheet (like Bounce) after rubbing against the wool. What happens to the static cling? Can you rub different times, measure the results and make a graph? If you can, you can make a graph to compare the results of different products. How do they compare? Do they take the same number of rubs to reduce the static cling? Which brands are most effective?
• Try comparing the effectiveness of different materials for producing a static charge. Does rubbing wool work better than rubbing silk? Design an experiment to test several different materials: silk, wool, nylon, polyester, plastic, metal, etc.
• For a more advanced experiment, try investigating static electricity in different conditions, temperatures and humidities (Brynie, 2005).

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