THE MAGNITUDE OF ELECTRIC FIELD IS kq/radius-square . IF THE Q[THAT IS CHARGE
] IS BIGGER IN MAGNITUDE OR IF THE DISTANCE BETWEEN THE CHARGE PARTICLE AND POINT CHARGE IS MINIMUM THAN WE CAN SAY THAT IT IS A STRONG ELECTRIC FIELD
Two plates with a voltage between them have an electric field in the space between them equal to the voltage divided by the distance. A single sphere at a high voltage has an electric field round it that decreases with distance. High voltage components have a strong electric field round them, and this can be dangerous, so it is usual to specify the maximum acceptable field and set a safe distance for people on that basis.
That's because there is no electric field inside the cage.
The net electric field inside a dielectric decreases due to polarization. The external electric field polarizes the dielectric and an electric field is produced due to this polarization. This internal electric field will be opposite to the external electric field and therefore the net electric field inside the dielectric will be less.
for apex its: a quantum field, a gravitational field
The electric field gets stronger as you get closer to an electric charge.
electric field lines represents electric field at that point but if it has break somewhere then it signifies the absence of electric field and it is not possible.....
That's because there is no electric field inside the cage.
An electric field can be represented diagrammatically as a set of lines with arrows on, called electric field-lines, which fill space. Electric field-lines are drawn according to the following rules: The direction of the electric field is everywhere tangent to the field-lines, in the sense of the arrows on the lines. The magnitude of the field is proportional to the number of field-lines per unit area passing through a small surface normal to the lines. Thus, field-lines determine the magnitude, as well as the direction, of the electric field. In particular, the field is strong at points where the field-lines are closely spaced, and weak at points where they are far apart. Electric Field intensity It was stated that the electric field concept arose in an effort to explain action-at-a-distance forces. All charged objects create an electric field which extends outward into the space which surrounds it. The charge alters that space, causing any other charged object that enters the space to be affected by this field. The strength of the electric field is dependent upon how charged the object creating the field is and upon the distance of separation from the charged object. In this section of Lesson 4, we will investigate electric field from a numerical viewpoint - the electric field strength. An electric field can be represented diagrammatically as a set of lines with arrows on, called electric field-lines, which fill space. Electric field-lines are drawn according to the following rules: The direction of the electric field is everywhere tangent to the field-lines, in the sense of the arrows on the lines. The magnitude of the field is proportional to the number of field-lines per unit area passing through a small surface normal to the lines. Thus, field-lines determine the magnitude, as well as the direction, of the electric field. In particular, the field is strong at points where the field-lines are closely spaced, and weak at points where they are far apart. Electric Field intensity It was stated that the electric field concept arose in an effort to explain action-at-a-distance forces. All charged objects create an electric field which extends outward into the space which surrounds it. The charge alters that space, causing any other charged object that enters the space to be affected by this field. The strength of the electric field is dependent upon how charged the object creating the field is and upon the distance of separation from the charged object. In this section of Lesson 4, we will investigate electric field from a numerical viewpoint - the electric field strength.
The net electric field inside a dielectric decreases due to polarization. The external electric field polarizes the dielectric and an electric field is produced due to this polarization. This internal electric field will be opposite to the external electric field and therefore the net electric field inside the dielectric will be less.
Because to completely describe it you must know both how strong it is (magnitude) and in what direction it points.
for apex its: a quantum field, a gravitational field
Two plates with a voltage between them have an electric field in the space between them equal to the voltage divided by the distance. A single sphere at a high voltage has an electric field round it that decreases with distance. High voltage components have a strong electric field round them, and this can be dangerous, so it is usual to specify the maximum acceptable field and set a safe distance for people on that basis.
An electric field can exist even without the presence of a magnetic field. An example of this is a stationary electric field.
The electrons of the permanent magnet would align the way the electromagnetic field passed through the magnet.
The electric field gets stronger as you get closer to an electric charge.
It's the electric field.
electric field lines represents electric field at that point but if it has break somewhere then it signifies the absence of electric field and it is not possible.....
The lines in each diagram represent an electric field. The stronger the field, the close together the lines are.