One coulomb is equal to the force of repulsion when a unit positive charge is placed from a similar charge at a distance of 1m.
The charge on a proton is positive and equal to +1 elementary charge, which is approximately 1.602 x 10^-19 coulombs.
Since protons and electrons carry the same but opposite charges, the charge of a single proton is often given in units as +1. More specifically, a proton's electrical charge is e divided by the square root of two, .707 x 0.16E-18 Coulomb. This is the effective (RMS) charge, or 0.113137E-18 Coulomb.
The charge of neutron is 0, as it is neutral. The charge of proton is 1.6x 10 to the power -19 coulomb. The charge of electron is -1.6x10 to the power -19 coulomb.
With relation to an electron the proton has a charge of -1, since the proton's charge is opposite of the electron's. However, the common notation of charge is relative to a proton's- therefore, it is more accurate to leave things in terms of a proton's charge. In terms of proton charge, a proton has a charge of +1.
The particle that most resembles a proton could either be a neutron or an electron, and we'll have to explain that. The proton has about the same mass as the neutron, while the electron has only about 1/1836th the mass of a proton. The masses of the proton and neutron are similar. And both particles are found in the nucleus of atoms. The proton has the same electrical field strength as an electron (only of opposite polarity), while the neutron has no charge. The proton and electron have the same coulomb charge on them, except the sign of the charge. Both particles are carriers of fundamental electrical charges. In these two ways, the proton could be said to be like either the neutron or electron. And how the observer "looks" at them will determine which "likeness" he sees.
Positive one, or 1.602 × 10−19 coulomb.
The charge on a proton is positive and equal to +1 elementary charge, which is approximately 1.602 x 10^-19 coulombs.
Since protons and electrons carry the same but opposite charges, the charge of a single proton is often given in units as +1. More specifically, a proton's electrical charge is e divided by the square root of two, .707 x 0.16E-18 Coulomb. This is the effective (RMS) charge, or 0.113137E-18 Coulomb.
1 microcoulomb is the equivalent of a millionth of a coulomb.
Coulombs. 1 Coulomb = 6,241,510,000,000,000,000 electron or proton charges (rounded to the nearest 10 trillion)
The charge of neutron is 0, as it is neutral. The charge of proton is 1.6x 10 to the power -19 coulomb. The charge of electron is -1.6x10 to the power -19 coulomb.
You can determine the attractive electrical force between an electron and proton using Coulomb's law. The force is directly proportional to the product of their charges, and inversely proportional to the square of the distance between them. The equation is F = k * |q1 * q2| / r^2, where F is the force, k is Coulomb's constant, q1 and q2 are the charges of the electron and proton, and r is the distance between them.
One ampere = one coulomb every second .
You can get awfully close. You can have any amount of charge that's a multiple of 0.000000000000000000160217646 coulombs. That's the charge on one electron or one proton.
The neutron allows more than one proton to combine to form a nucleus. The nuclear force overcomes the coulomb repulsion.
The charge of neutron is 0, as it is neutral. The charge of proton is 1.6x 10 to the power -19 coulomb. The charge of electron is -1.6x10 to the power -19 coulomb.
1 statcoulomb is equal to 3.33564 x 10^-10 coulombs.