1. Electric field lines of force originate from the positive charge and terminate at the negative charge.
2. Electric field lines of force can never intersect each other.
3. Electric field lines of force are not present inside the conductor, it is because electric field inside the conductor is always zero.
4. Electric field lines of force are always perpendicular to the surface of conductor.
5. Curved electric field lines are always non-uniform in nature.
Gravity field Magnetic field Temperature field
Magnetic field lines show the direction of the magnetic field, the magnitude of the magnetic field (closeness of the lines), and the shape of the magnetic field around a magnet or current-carrying wire.
The electric field produced by a charged particle, which exerts a force on other charged particles within its influence. The electric field between the plates of a capacitor, which stores energy in the form of electric potential. The electric field surrounding a lightning bolt, which can be extremely intense and dangerous.
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.
The three elements that produce a magnetic field are electric currents, magnetic materials, and changing electric fields. These elements interact to generate magnetic fields and are fundamental to understanding electromagnetism.
Gravity field Magnetic field Temperature field
Magnetic field lines show the direction of the magnetic field, the magnitude of the magnetic field (closeness of the lines), and the shape of the magnetic field around a magnet or current-carrying wire.
The electric field produced by a charged particle, which exerts a force on other charged particles within its influence. The electric field between the plates of a capacitor, which stores energy in the form of electric potential. The electric field surrounding a lightning bolt, which can be extremely intense and dangerous.
The infield lines are about three inches wide. The wider lines surrounding the field and end zones are a yard wide.
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.
The three elements that produce a magnetic field are electric currents, magnetic materials, and changing electric fields. These elements interact to generate magnetic fields and are fundamental to understanding electromagnetism.
Yes. The electric field in physics is represented by a vector, it has three components governing the field strength in the up-down, left-right and forward-backwards directions.
Three examples of vectors are force (e.g., push or pull), velocity (e.g., speed and direction of an object's motion), and electric field (e.g., direction and magnitude of an electric force on a charged particle).
Three things you need to make an electromagnetic are a magnetic field, an electric current, and a conductor or coil of wire. When an electric current flows through the conductor, a magnetic field is created around it, resulting in an electromagnetic effect.
Light waves vibrate in three dimensions: they have electric field and magnetic field components that oscillate perpendicular to the direction of propagation.
The main effects of an electric current are the generation of heat (thermal effect), the production of light (light effect), and the creation of a magnetic field (magnetic effect).
The electric field produced by a dipole at a distance is given by the formula E = 2kP/r^3, where k is the electrostatic constant, P is the dipole moment, and r is the distance from the dipole. This electric field exerts a force on a test charge q placed in the field, given by F = qE. Therefore, the force on a charge due to a dipole moment is directly proportional to the dipole moment and the charge, according to these equations.