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The National MagLab is funded by the National Science Foundation and the State of Florida.

Watch & Play

Watch & Play
See the science at play in these electrifying demonstrations and animations that illuminate the invisible electromagnetic forces. Or have your own fun with puzzles, games and a collection of interactive tutorials.

Interactive Tutorials
These demonstrations about laws and tools associated with electricity and magnetism allow you to adjust variables at and to visualize invisible forces — which makes them almost better than the real thing.

See-Thru Science
Seeing is believing. In these animations, we show you what electricity and magnetism might look like if they weren't invisible.

Game & Quizzes
Learn about electricity and magnetism — and have some fun while you're at it!

Science Demos
How do Maglev trains work? What are comets made of? How do bugs walk on water? This section demonstrates these and other concepts related to magnetism, electricity and other areas of science.
Read Science Stories

Read Science Stories
Whether you prefer science stories that are short & sweet, long & detailed, or in graphic form, these stories spell out the basics of electricity and magnetism and the exciting discoveries that magnets enable in easy-to-understand language.

Science simplified
Whether you prefer your science short & sweet or long & detailed, we spell it out for you here in easy-to-understand language.
Comic Collection
Read fun science stories told in comic strip style.
The Art of Science
There is beauty and art in science. Gaze on these stories of discoveries that could be featured on museum walls instead of scientific journals.

Left Fields
Explore these surprising, unconventional and sometimes downright strange stories about high magnetic field research.
Science Step-by-Step
These special science graphics explain science stories in digestible steps and include optional detours for readers wanting more background to customize your reading journey.
Explore History

Explore History
Electricity and magnetism discoveries span the centuries. Peruse the people, products and places related to electricity & magnetism from across space and time.

Pioneers
Get to know these pioneers who went down in history for their groundbreaking work, including scientists behind common terms such as Amp, Celsius, Kelvin, hertz and tesla.

Museum
From the world's first compass to the magnetic force microscope and beyond, explore a variety of instruments, tools and machines throughout history.

Timeline
Our timeline takes you through the highlights of electricity and magnetism and across the centuries.

Places
Take a field trip to these high magnetic field landmarks around the globe.
Try This at Home

Try This at Home
Science can happen anywhere! Try these hands-on science activities at home, school, club, or wherever you might find yourself! They’re easy, fun and can be done with stuff you have around the house.

Activity Books Atomic Ornament Build a Bacteria Brain Cerebrum Hat Candy DNA Candy Neuron Crystal Growing DIY Kaleidoscope Drawing Magnetic Field Lines Fill-in Fractal

Groovin Ghost Make a Compass Activity Makeshift Magnets Making Electromagnets Making Ferrofluids Möbius Strip See Iron in Food Shapeshifting Slime Solar System Hats
Plan a Lesson

Plan a Lesson
Looking for a lesson plan for science class or to incorporate science concepts into other subjects? These lessons plans offer detailed directions for K12 teachers to conduct hands-on lessons and align with next generation science standards.

Compasses Demagnetizing Electric Motors Electromagnets Magnet Exploration

Magnetic Putty Magnetizing and Unmagnetizing Making a Circuit Pancake Particles Plotting Electric Field Lines

Galvanometer

A galvanometer detects and measures small amounts of current in an electrical circuit.

The first galvanometer was assembled by German mathematician and physicist Johann Schweigger, who called it a multiplier.

A galvanometer consists of a coil mounted so that it’s allowed to pivot freely within a magnetic field created by the poles of one or more permanent magnets. A needle is attached to the coil.

When electricity is allowed to pass through the coil, the magnetic field generated by the current-carrying wire interacts with the field of the permanent magnets, generating torque that rotates the coil. The deflection of the galvanometer’s needle is proportional to the current flowing through the coil. Here, we show you the concept of those interacting magnetic fields.

Instructions

See the simple circuit set up between the battery and the coil.
Note how the coil is mounted between two permanent magnets, with opposite poles facing the coil.
Click the power button to close the knife switch and send an electric current to the coil. Notice what happens. The magnetic field generated by the current in the coil is at a right angle to the plane of the coil. This magnetic field causes the coil to swing, as the south pole of the coil's magnetic field is attracted to the north pole of the bar magnet field.
Click the flip battery button to reverse the direction of current through the coil. This reverses the poles of the magnetic field around the coil, so the coil swings in the opposite direction.
To stop the flow of electricity through the coil, click the off button.

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