# Frequent question: Is it possible for an electric field to exist at some point in space at which there is no charge?

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Q20 Is it possible for an electric field to exist at some point in space at which there is no charge? Yes, all we need to have is a charge somewhere in space that can exert a force on a positive test charge brought to that point in space.

## Is it possible for an electric field to exist in empty space?

So Electric Fields are vectors (they have magnitude and direction) Electric Fields surround electric charges. Electric Fields exist in empty space (think of fields as a property of space!) … It is present at any (and every) point in space.

## Can there be an electric field at a point where there is no charge?

Any time there is a charge it creates an electric field in its vicinity. Q1,Yes, there can be an electric field at a point with no charge. But there will be no force from it untill a point with a charge is there.

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## How can we represent the electric field if it exists at all points in space?

Electric Field Diagrams

At every point in the region of space where the electric field exists, there is an electric field vector. Because the electric field is uniform, all the vectors are of the same magnitude and hence, we would draw all the arrows representing the electric field vectors, the same length.

## Can an electric field exist in air?

On an ordinary day over flat desert country, or over the sea, as one goes upward from the surface of the ground the electric potential increases by about 100 volts per meter. Thus there is a vertical electric field E of 100 volts/m in the air.

## Why can’t electric field lines cross?

Electric field lines cannot cross. … This is because they are, by definition, a line of constant potential. The equipotential at a given point in space can only have a single value. If lines for two different values of the potential were to cross, then they would no longer represent equipotential lines.

## Is there an electric field everywhere?

Think of one charge as producing an electric field everywhere in space. … The force on another charge introduced into the electric field of the first, is caused by the electric field at the location of the introduced charge.

## How do you know if an electric field is positive or negative?

If the charge is positive, field lines point radially away from it; if the charge is negative, field lines point radially towards it. Electric field of positive point charge: The electric field of a positively charged particle points radially away from the charge.

## Why do electric field lines go from positive to negative?

The direction of the electric field is always directed in the direction that a positive test charge would be pushed or pulled if placed in the space surrounding the source charge. … As such, the lines are directed away from positively charged source charges and toward negatively charged source charges.

## What would happen if there was no electric field?

But what would happen if Earth’s magnetic field disappeared tomorrow? A larger number of charged solar particles would bombard the planet, putting power grids and satellites on the fritz and increasing human exposure to higher levels of cancer-causing ultraviolet radiation.

## How electric field is generated?

The electric field is produced by stationary charges, and the magnetic field by moving charges (currents); these two are often described as the sources of the field. … The force created by the electric field is much stronger than the force created by the magnetic field.

## Why are electric fields important?

Electric fields (e-fields) are an important tool in understanding how electricity begins and continues to flow. Electric fields describe the pulling or pushing force in a space between charges. … The electric fields of single charges. A negative charge has an inward electric field because it attracts positive charges.

## What is the relation between electric field and force?

The electrostatic force exerted by a point charge on a test charge at a distance r depends on the charge of both charges, as well as the distance between the two. The electric field E is defined to be E=Fq E = F q , where F is the Coulomb or electrostatic force exerted on a small positive test charge q.

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