# How to Make a Salt Water Circuit

Everyone tells you not to keep electrical appliances in the bathroom near the tub when you are enjoying a long, hot soak. It is nice to listen to music while in the tub but keeping the radio on the edge of the bathtub.........definitely not a great idea!

Most water contains minerals and salts. Those of us who like to have softer water with an enjoyable aroma may also add washing soda which provides even extra salts. But why is this a problem? Read on dear readers and discover the dangers of electrical appliances near bathtubs.

Consider plain table salt or sodium chloride which is made up of sodium and chloride ions. All atoms like to have their orbital shells filled with a certain number of electrons. If it has far fewer than the required number of electrons, the atom tends to give up electrons and if it has almost the right number, the atom tends to acquire electrons. Sodium (Na) has eleven electrons. It has one too many to have its last shell filled so it will give up an electron to an atom that requires one. Chlorine has 17 electrons and just needs one more electron to fill its outer orbital shell. When chlorine and sodium come in contact, sodium will give up one of its electrons to chlorine. Although they now have their outer electron shells filled, they each have changed chemically. Adding an electron changes the charge of chlorine from neutral to a negative charge. Chlorine becomes a negatively charged ion. Sodium, having lost an electron changes from neutral to a positive charge. Sodium becomes a positively charged ion. As positive and negative ions, chlorine and sodium are strongly attracted and become the compound sodium chloride or table salt.

As a dry compound, sitting on your table, the strong attraction between the two ions in table salt is very strong and is nearly impossible to break. However, put this salt into water and these ionic bonds break very easily because of their electrical attraction to water. In other words, the table salt dissolves in water because of the weakening of the ionic bonds while in water. Na+ and Cl- ions float freely in the solution. Because there are positive and negative charges, water containing salts (and most water except pure water does contain some salt ions) is an excellent conductor of electricity. If you are in a bathtub and your live electrical appliance falls in the tub with you, the electrical current is carried through the water and directly to you often resulting in grave injury or death due to electrocution. As such, never treat electricity in a cavalier manner. Always take great caution and even this experiment should be done with parental supervision when performed by younger children. And please, never, never keep electrical appliances near your tub!

## Materials to Make a Salt Water Circuit

• large mouthed cup
• tape - masking or cellophane
• distilled water or city tap water (well water tends to contain too many minerals which will distort your findings)
• table or sea salt
• 9-volt battery
• aluminum foil
• small voltage light bulb (3.7-volt would work well)
• light bulb socket
• two popsicle sticks or two stiff pieces of cardboard of like size
• insulated copper wire
• scissors or wire strippers
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## Assembling the Salt Water Circuit

1. Take two popsicle sticks and wrap them completely in one layer of aluminum foil. These will be the electrodes.
2. Cut three 6 to 7 inch pieces of insulated copper wire.
3. Strip about ½ inch of insulation off of each end using scissors or wire strippers.
4. Connect the stripped part of one wire end to the positive terminal of the battery and secure it with the tape.
5. Connect the other stripped end of the same wire to one side of the light bulb socket.
6. Using the second piece of wire, connect one of the stripped ends to the other side of the light bulb socket.
7. Take the other stripped end of the same wire and tape onto the aluminum foil near the top of one of the 'electrodes'.
8. Using the last piece of wire, connect one stripped end to the negative terminal of the battery and secure it with the tape.
9. Connect the other stripped end of the same wire to the second electrode in the manner outlined in step 7.
10. Check all your connections in the circuit and make sure they are secure. To test your circuit, make a complete circuit by touching the two electrodes. The light bulb should light up. If it does not check your connections again and make any necessary adjustments and try again.

## Using the Salt water Circuit in Water

1. Pour distilled water into the cup so it is ½ to ¾ full.
2. Without letting them touch, put both electrodes into the water.
3. What happens to the light bulb?
4. Removing the electrodes from the cup, stir in 2 teaspoons of salt into the water until it dissolves. Repeat step 2.
5. What happens to the light bulb in this case?

## The Science Behind the Salt water Circuit

When dissolved in water, sodium chloride (the chemical name for salt) dissociates into positive sodium ions and negative chloride ions. As there are positive and negative charges present in the salt water solution, electricity can be conducted from one electrode to the other of the salt water circuit. These charged ions complete the circuit causing the light bulb to light up. Try varying the amount of salt dissolved in the water to see if the brightness of the light bulb changes.

This content is accurate and true to the best of the author’s knowledge and is not meant to substitute for formal and individualized advice from a qualified professional.