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Activities Science At Home

Make a Battery Like Volta’s First Battery

Allessandro Volta was an Italian physicist and chemist who invented the first electric battery in 1799. He experimented with chemically generating electricity using dissimilar metals immersed in saltwater. He determined that zinc and copper produced the best results. He made a voltaic pile by stacking alternating zinc and copper discs with saltwater soaked cloth or cardboard between the discs.

Anyone can perform experiments similar to Volta’s using materials that can be found in many homes or purchased at a hardware, building supply or general merchandise store.

Single-cell Battery

To make a single-cell battery with zinc and copper, the required materials are:

1.     About a foot of bare copper wire. Solid wire is best, but stranded wire will work. Thicker wire is better. Most copper wire is covered with insulation that must be removed.

2.     Something that is coated with zinc (galvanized). Many steel items such as screws, nails and paperclips are zinc coated. Anything that has a silver color and is attracted to a magnet is likely zinc coated or has a coating that contains zinc.

3.     A glass or plastic container that is large enough to contain the zinc item with a little extra space.

4.     Enough vinegar to fill the container (preferably distilled white vinegar) or salt to mix with water.

5.     Something to detect the voltage produced by the battery. An inexpensive analog multimeter similar to the one shown below can be purchased for about $15. Alternatively, the voltage can be felt as a tingle between the two wires when touched with your tongue.

6.     Multimeter (optional)

Procedure

Cut the wire into two pieces. Tightly attach one piece of wire to the zinc item as shown below. 

Fill the container with vinegar or salt water and insert the copper wire and zinc item as shown below. The voltage will be less than the voltage of a standard 1.5-volt dry cell. If you hold the two wires close together, but not touching, you can touch them with your tongue to feel that a voltage is produced.

Multi-cell Battery

Several cells can be connected in series to produce a higher voltage as shown below. As shown, the battery will light an LED, but it will not produce enough current to light a flashlight bulb.

Experimentation

1.    What happens to the voltage when an LED or flashlight bulb is connected?

2.     What happens if you use a copper wire with more surface area? Cut a longer wire and bend it together to fit in the jar.

3.     For the zinc piece, try different sizes and materials.

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News

Covid-19 Test – Wisconsin Connection

In 1970, Howard M. Temin of the UW-Madison McArdle Laboratory for Cancer Research announced his discovery of an enzyme called reverse transcriptase (RT). RT is the key component of a research technique called reverse transcription polymerase chain reaction (RT-PCR). RT-PCR has become an essential diagnostic tool for detecting infectious agents including Covid-19.

The Nobel Prize in Physiology or Medicine 1975 was awarded jointly, 1/3 each, to Howard Temin, David Baltimore, and Renato Dulbecco “for their discoveries concerning the interaction between tumor viruses and the genetic material of the cell.” These discoveries are the basis of much of today’s biotechnology industry.

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Activities

Home Science Activities

The Wisconsin Science Museum is pleased to present science activities that can be done at home using materials that are found in most homes.

Prehistoric Electricity

Demonstrate the very first electrical experiment ever performed using materials found in most homes.

The History of Magnetism

Learn about he history of magnetism and make a compass using materials found in most homes.

Electricity Can Make Magnetism

Show that an electric current produces magnetism using materials found in most homes.

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Activities

The History of Magnetism

… and how to make a compass using material that is found in most homes.

Human knowledge of magnetism began with magnetic stones. Prehistoric people observed that certain stones were attracted to each other and that iron was attracted to them. They discovered that if one of these stones is suspended so that it can turn freely, it always turns to a certain position. By noting the position of the stone the stone could be used to determine which direction is north without observing the North Star. In English such a stone came to be called a lodestone. In ancient Greece, a particularly good type of lodestone was called magnetite because it was found in an area of Greece called Magnesia. The word magnet came from magnetite. We now know that magnetite is an iron ore that has become naturally magnetized.

Ancient people made compasses in several ways including magnetizing iron needles. There are also several ways to make a compass at home. A compass requires something fairly light that is either a very small magnet or something light that can be magnetized using a permanent magnet. Most homes have refrigerator magnets, cupboards with magnetic latches or a screwdriver that has a magnet in it. A cupboard-door magnet can be used without removing it from the door.

In addition to a magnet, this project also requires a twist-tie like the ones used to close a bread bag, a straight sewing pin and a piece of heavy cardboard.The twist-tie that keeps a bread bag closed has a soft iron wire inside.

Magnetize the twist-tie by stroking it with one end of a magnet from the center toward one end several times as shown below.

A 4-inch square piece of heavy cardboard is required for the base. A straight sewing pin is required for the compass needle to pivot on. Draw a circle on the cardboard and mark it with the points of the compass as shown. Insert a straight pin from the back side of the cardboard.

Carefully measure the twist-tie and mark the center. Bend a flat-bottom “U” shape in the center as shown. The “U” must be deep enough so that the twist-tie can be balanced on the pin and turn freely without touching the cardboard. When you have successfully balanced the twist tie it should point north.

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Activities

Electricity Can Make Magnetism

Electromagnetism can be demonstrated using items that can be found in many homes.

In 1820, Hans Christian Orsted turned on an electric current during an electrical demonstration and noticed that the needle of a nearby compass moved. He had just made one of the most important discoveries in the history of electricity. An electric current causes magnetism. Electromagnetism is used to operate electric motors, one of the most important uses of electrical energy.

Orsted’s discovery was accidental. His compass happened to be near a demonstration using electric current. After his initial accidental observation, he positioned his compass carefully for additional observations.

Replicating Orsted’s Discoveries

The following pictures illustrate some more careful observations using a dry cell battery, a piece of wire and a compass. To do this at home, any piece of metal wire can be used. Copper or aluminum would be best. Even a narrow strip of aluminum foil will work. The compass will be attracted to steel wire in the absence of an electric current, so steel wire may not work as well. A D-cell is shown in the pictures, but an AA-cell will work also. A triple A cell will probably work. The demonstration draws quite a bit of current, so it could deplete the smaller cells pretty quickly.

The wire in the first few pictures is an old piece of lamp cord that has deteriorated to the point hat it is no longer safe for it’s original use. It is fine for use in this demonstration. The cord has two conductors, but only one is needed, so the ends of the wire have been twisted together to avoid having to figure out which is which. The insulation at the ends of the cord has been scraped off with a knife.

Here, the compass has been positioned with the cord underneath arranged to match the direction of the compass needle. One end of the cord is under the dry cell, making contact with the negative end. If the battery is positioned too close to the compass, the compass needle may be attracted to the steel battery case.

When the free end of the wire is touched to the positive terminal of the battery, as shown below, the compass needle deflects. Note that the wire may get hot enough to make holding it to the dry cell uncomfortable.

The magnetic field surrounds the wire, so that the compass needle points in the opposite direction when it is under the wire. The compass needle would point at a right angle to the wire if not for the effect of the earth’s magnetic field. A higher current in the wire would make the needle angle closer to a right angle with the wire.

Here the wire is vertical, and three compasses show the magnetic field around the wire.

This picture shows how aluminum foil can be used instead of wire.

If you don’t have a compass, build your own. Another activity on this site shows how to do it.

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Activities

Prehistoric Electricity

… and how the very first electrical demonstration can be performed using materials found in every home.

Human knowledge of electricity began with lightning, electric fish and amber.

Lightning

Prehistoric people observed lightning in the sky during storms.  It made a bright light and a powerful noise. It could kill people and animals. It sometimes struck trees causing fire. It was once thought to be fire from the sky. It is now known that lightning is electrical.

Electric Fish

There are several types of fish and eels that can sting a person in a way that causes numbness in the area of the sting, but does not cause a wound. These creatures were known in prehistoric times but not understood. We now know that they have a special defensive organ that generates electricity.

Amber and The Very First Electrical Experiment

Amber is resin from trees that has solidified over time. It looks and feels like hard plastic. It was gathered and saved by ancient people for decorative objects and jewelry purposes. Some pieces of amber have insects trapped inside.

Ancient people discovered that, after amber is rubbed with animal fur, it has the power to attract light materials such as dust and small feathers (down). This was the very first electrical experiment.

The ancient Greeks called amber “electrum” after their name for the sun, “elector.” Thales of Miletus, one of the seven wise men of Ancient Greece was said to have believed that amber must contain life to have the power to move things. We know now that the force of amber is due to static electricity. William Gilbert gave us the word electricity by his use of the Latin word electricus to describe electrostatic phenomena as “amber-like.”

Electrical Charge

All matter is composed of atoms.  Atoms are composed of electrons, protons and neutrons. Electrons have a negative electrical charge, protons a positive charge and neutrons no charge. The protons and neutrons are tightly bound together to form the nucleus or center of the atom. The electrons are less tightly bound. The number of protons it an atom determines the atomic number and identity of the chemical element that it forms. Element number 1, Hydrogen has one proton. Element number 92 is Uranium with 92 protons.

Atoms in their “normal” state have an equal number of protons and electrons, so their positive and negative charges are balanced. That means that “normal” materials have no electrical charge. However, friction often causes electrons to transfer from one material to another. That is called the triboelectric effect. Some materials hold onto electrons more tightly than others. Amber holds onto electrons more tightly than cloth or animal fur, so when it is rubbed with those materials it tends to accumulate extra electrons and become negatively charged.  Feathers, pieces of hair, dry skin and other materials that make dust tend to leave electrons behind when they are separated from there origin. That gives them a positive electrical charge. That is why amber that has been rubbed by fur attracts dust and small feathers.

Triboelectric Series

The triboelectric series shows the relative tendencies of materials to become positively or negatively charged by friction. Rubbing together two materials that are far apart on this table results in the highest level of electrostatic charge.

Electrostatic Experiment

The first two of the following pictures re-create the ancient experience of picking something up using amber that has been rubbed by animal fur. The third picture shows how anyone can re-create this experience by rubbing plastic with cloth.

A piece of amber on rabbit fur

Dry lint picked up by a piece of amber that has been rubbed with rabbit fur

Dry lint picked up by a plastic bottle that has been rubbed with cloth

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News

Science Hall of Fame

The Wisconsin Science Museum’s Hall of Fame honors scientists, technicians, engineers and mathematicians who were educated in Wisconsin or performed notable work here. Our Hall of Fame member pages briefly tell their stories and provide links to additional information about them. A few pages are now available on the web site and additional pages will be added frequently. Check the site often for new pages.

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Events

Homegrown Discovery Presentation

Embedded Computers in Wisconsin

Postponed indefinately

To be held in the UW Space Place adjacent to the Science Museum. Sponsored by the Madison Section of the Institute of Electrical and Electronics Engineers. The exhibit area of the Space Place and the Science Museum will be open after the presentation. For additional information and sign-up, visit: Embedded Computers in Wisconsin.

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Past Events

Mini Maker Faire

DateSunday November 24
Time10am – 4pm
PlaceMonona Terrace

Come find our booth at the Mini Maker Faire! Learn what makes LEDs light up and motors spin, and build your own circuit you can take home.

For more information, visit https://madison.makerfaire.com/.

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News

Museum Updates

The Wisconsin Science Museum has moved from the initial location in the former downtown location of Madison College. Our new location at 2300 S Park St. is still under construction. Since our move, we have participated with a table at UW-Madison Science Expeditions 2019. On November 24th, we will be at The Madison Mini Makers Faire.

Exhibits in the museum are designed to inspire interest in science, technology, engineering and mathematics. We celebrate Homegrown Discoveries, the achievements of people working in Wisconsin and people who were educated here. Visitors can see technological creations up close and learn about them. Some technology can be seen in action. There are opportunities to touch things, make things and operate things.