Electrical fields are non-directional and directional, scalar and vector.
For example, the E-field is the derivative of the the scalar voltage;
XV= [d/dr, Del][ -ezc/r, ]= [ezc/r2, ezc/r3 R]
The result is a scalar E-field and a vector E-field, or a Quaternion E-field.
This same is true for the gravitational field:
FGravity = [d/dr, Del] [ -mGM/r, ] = [mGM/r2 , mGM/r3 R]
Electric fields are similar to magnetic fields, and can be "compressed" by the imposition of other electric or magnetic fields.
Moving electric charges create electromagnetic fields.
Positive electric fields attract negative charges while negative electric fields attract positive charges.
Electric fields start on positive charges and terminate on negative charges..
Yes, electric current does create magnetic fields
Electric fields are similar to magnetic fields, and can be "compressed" by the imposition of other electric or magnetic fields.
Moving electric charges create electromagnetic fields.
Positive electric fields attract negative charges while negative electric fields attract positive charges.
Electromagnetic radiation. Energy can also be transmitted by electric fields, by magnetic fields, and by gravitation.Electromagnetic radiation. Energy can also be transmitted by electric fields, by magnetic fields, and by gravitation.Electromagnetic radiation. Energy can also be transmitted by electric fields, by magnetic fields, and by gravitation.Electromagnetic radiation. Energy can also be transmitted by electric fields, by magnetic fields, and by gravitation.
Electric fields start on positive charges and terminate on negative charges..
Yes, electric current does create magnetic fields
no
Vibrations in electric and magnetic fields create electromagnetic radiation.
The two are related because an Electric current produces Magnetic Fields
yes
Michael Faraday first introduced the concept of electric fields/
Yes