Gravitational: Isaac newton, Albert Einstein, George Gamow, Fred Hubble Electric: Charles Augustin de Coulomb, James Clerk-Maxwell, Guglielmo Marconi, Albert Einstein, Chris Quigg
No. The sum of the gravitational field and the electric field is a useless concept.
for apex its: a quantum field, a gravitational field
Introduce two opposite charged objects one AT A TIME and if they move IN THE SAME DIRECTION, they are in a gravitational field, if they move IN DIFFERENT direction they are in an electric field.
Energy is stored in fields by creating potential energy through the configuration or arrangement of the field. For example, in an electric field, energy is stored as electric potential energy when charges are separated. In a gravitational field, energy is stored as gravitational potential energy based on an object's position in the field.
The three types of fields in physics are gravitational fields, electric fields, and magnetic fields. These fields describe the forces that act on objects within their influence, such as the force of gravity between masses in a gravitational field or the force between electric charges in an electric field.
No. The sum of the gravitational field and the electric field is a useless concept.
for apex its: a quantum field, a gravitational field
Introduce two opposite charged objects one AT A TIME and if they move IN THE SAME DIRECTION, they are in a gravitational field, if they move IN DIFFERENT direction they are in an electric field.
Scientists use a positive test charge to determine the direction of the electric field vector. The electric field direction is defined as the direction in which a positive test charge would move when placed in the field. Thus, observing the force experienced by the positive test charge allows scientists to infer the direction of the electric field at that point.
Energy is stored in fields by creating potential energy through the configuration or arrangement of the field. For example, in an electric field, energy is stored as electric potential energy when charges are separated. In a gravitational field, energy is stored as gravitational potential energy based on an object's position in the field.
The three types of fields in physics are gravitational fields, electric fields, and magnetic fields. These fields describe the forces that act on objects within their influence, such as the force of gravity between masses in a gravitational field or the force between electric charges in an electric field.
No. Earth's gravitational field is due to the large mass within it; the electromagnetic field is due to the movement of the metals in its core. There are also the standard differences between a gravitational and an EM field.
A proton is surrounded by an electric field, which interacts with other charged particles. It also interacts with a magnetic field under certain conditions, such as when it moves through a magnetic field.
Electric potential energy, like gravitational potential energy, represents the stored energy an object has due to its position or configuration in a field. Both types of potential energy depend on the object's distance or position relative to a source (electric charge for electric potential energy and mass for gravitational potential energy). The formulas for calculating electric and gravitational potential energy have similar mathematical forms involving distance and a constant.
because it has the hydro electric power to control the earths magnetic field
An electric field E is produced by a punctual electric charge q or by any electrically charged object. The Efield produced by a charge is analogous to the gravitational field g produced by a mass : Fg= mg the same way Fe = qE.
The gravitational field strength is important in understanding how objects move in space because it determines the force of gravity acting on them. This force affects the motion and interactions of objects, such as planets and satellites, in space. By knowing the gravitational field strength, scientists can predict and explain the behavior of these objects in space.