A little over one-third of the total energy density of the world’s entire electricity supply comes from a single, tiny magnet at the center of an electric circuit.

The world’s largest magnet, the 1.8-billion-watt-hour Franklin Magnet, was discovered in 1935, and it’s the only magnet that can be so large.

Now, researchers are building a magnet that could hold as much as 3.5 billion watts.

The magnet could be used to power a small amount of renewable energy sources such as solar, wind, and nuclear power plants, said the researchers, who are affiliated with the University of California at Berkeley.

The researchers say the magnet could provide energy for many energy-intensive applications, such as in a battery, as well as powering satellites.

 They also believe the magnet’s large size could allow for a larger magnet to be made by applying the same technique to a smaller one.

“The Franklin magnet is a unique magnet in that it has an attractive, self-aligning structure that allows it to provide enough energy to sustain many applications,” said senior author Christopher J. Lohse, a UC Berkeley physics professor.

The magnet’s size and shape allow it to absorb and convert sunlight, heat, and radiation in its core, he said.

The team says its magnetic field is so strong that it can deflect the energy from incoming electrons and force them to travel in a different direction.

“It’s a really nice feat of engineering, and we think it’s really promising in the energy field,” Lohste said.

Lohse said he and his team are building the magnet using a technique called resonant resonance, which uses electromagnetic forces to create the magnetic field.

A magnetic field can deflect an incoming electron or deflect an outgoing photon, and they work together to create an electromagnetic field.

But a magnet has to have an attractive structure, meaning it has to be stable and maintain a constant electric field, Lohs said.

It also has to withstand the energy of electrons and photons.

Lihse’s team is using a magnet known as a magnetotron, which has been designed to perform this task.

The design is made of a platinum-hydroxide-iron oxide (PHEO) layer, which can withstand intense magnetic fields for longer periods of time, and which the researchers are using to build the magnet.

They have found that a PHEO layer can have up to 10 times the electric field strength of a standard magnet, which is about 100 times stronger than the strongest magnetic field in the world, the researchers said.

LOHse said the magnetic fields generated by the magnet will be stronger than those produced by any other magnetic materials known to man.

It is not yet clear if the magnetic properties of the magnetotrons could be improved by adding a second magnet, Lihs said, adding that he believes his team’s magnet will do this.

In a future version of their device, they are adding a layer of material that would give the Franklin magnet the ability to deflect incoming electrons.

This could be done by adding additional magnets on the outside of the core.

In the future, LOHs and his colleagues are planning to build a magnet with the capability of creating a magnetic field larger than that of the magnetic core of the Franklin Magnet.

They are currently working on building a small version of the larger magnet.

The researchers said the device could also be used in a power grid, to make solar panels that could absorb more energy.

More about magnet, magnetotronics, magnet, science, magnetism source ABC New article A magnet is the electric force that is generated when two charges attract each other, and the magnet can act as the source of the force.

It is also known as the magnetofugal force.

Because a magnet cannot be seen with the naked eye, scientists have known for some time that they exist, and have found magnetotronic devices that can generate and repel electric charges, or attract them to an object.

Magnetotronics uses electromagnetic force to change a charged object’s magnetic field, creating an electric field.

A magnet’s electric field is a function of the strength of its magnetic material, which acts as a “field generator.”

The strength of the field generator determines how strong the field is.

This is how a magnet can generate an electric current in an electric system.

One of the key problems in magnetotonics research is how to create a magnet.

One way is by adding magnetotrope or other electrical components to the magnet, called a magnetocouple, which creates a magnet field.

Another is by building an electromagnetic device called an antenna.

An antenna creates a magnetic resonance in an electrical circuit.

Researchers have discovered magnetotropic devices that generate electric fields that can repel, or be absorbed by, incoming electromagnetic fields, and are called magnetic dipoles.

For example,