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The magnitude of the electric potential is dependent upon the particle's charge and the electric field strength.
I'm not sure what this question really means - should it be more like "what two things affect the force between two electric charges?" If this is correct then the answer is probably: 1. The amount of charges. 2. The distance between the charges.
Near the poles, weakest at the midpoint between them
Experiments have shown that the electric force between two objects is proportional to the inverse square of the distance between the two objects. The electric force between two electrons is the same as the electric force between two protons when they are placed as the same distance. This implies that the electric force does not depend on the mass of the particle. Instead, it depends on a new quantity: the electric charge. The unit of electric charge q is the Coulomb (C). The electric charge can be negative, zero, or positive. The electric charge of electrons, protons and neutrons are -1.6 x 10-19, 1.6 x 10-19, and 0. Detailed measurements have shown that the magnitude of the charge of the proton is exactly equal to the magnitude of the charge of the electron. Since atoms are neutral, the number of electrons must be equal to the number of protons. The precise magnitude of the electric force that a charged particle exerts on another is given by Coulomb's law.
Those having only magnitude but no direction are known as scalar quantity. Time, mass, work, power, electric current, electric charge, moment of inertia, magnetic flux, electric flux and so many are found to be scalar in this world.
Electric field is dependent on the magnitude of the electric charge, E = qzc/r2
The magnitude of the electric potential is dependent upon the particle's charge and the electric field strength.
The magnitude of the electric potential is dependent upon the particle's charge and the electric field strength.
The electric charges of the proton and electron are equal in magnitude (size, strength), and opposite in sign.
I'm not sure what this question really means - should it be more like "what two things affect the force between two electric charges?" If this is correct then the answer is probably: 1. The amount of charges. 2. The distance between the charges.
A proton has a positive charge which is equal in magnitude but opposite to the charge on an electron, which is negative.
Yes, because each proton carries a positive electric charge that is equal in magnitude to the negative electric charge on each electron.
Near the poles, weakest at the midpoint between them
Experiments have shown that the electric force between two objects is proportional to the inverse square of the distance between the two objects. The electric force between two electrons is the same as the electric force between two protons when they are placed as the same distance. This implies that the electric force does not depend on the mass of the particle. Instead, it depends on a new quantity: the electric charge. The unit of electric charge q is the Coulomb (C). The electric charge can be negative, zero, or positive. The electric charge of electrons, protons and neutrons are -1.6 x 10-19, 1.6 x 10-19, and 0. Detailed measurements have shown that the magnitude of the charge of the proton is exactly equal to the magnitude of the charge of the electron. Since atoms are neutral, the number of electrons must be equal to the number of protons. The precise magnitude of the electric force that a charged particle exerts on another is given by Coulomb's law.
No,because electric field (force/charge) is a vector quantity, i.e. , it has both magnitude as well as direction.
Those having only magnitude but no direction are known as scalar quantity. Time, mass, work, power, electric current, electric charge, moment of inertia, magnetic flux, electric flux and so many are found to be scalar in this world.
The magnitude of the test charge must be small enough so that it does not disturb the distribution of the charges whose electric field we wish to measure otherwise the measured field will be different from the actual field.