Charge of photon = Q1 = Q2 = 1.6x10-19 C
Distance of separation = r = 12x10-15 m
εₒ = 8.85 x10-12 Fm-1
Electric Force = (Q1Q2) / (4πεₒr2)
Electric Force = {1.6x10-19}2 / {4 x π x 8.85 x10-12 x (12x10-15)2}
Electric Force = 1.598543057… N
Electric Force ≈ 1.60 N
Between protons and electrons.
strong nuclear force which acts between all nucleons keeps them together
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.
Answer this What is the electric force acting between two charges of 0.0042 C and −0.0050 C that are 0.0030 m apart question…
No, it is attractive. The strong nuclear force, as it is known, is what overcomes the coloumbic repulsion of the positively charged protons, which would otherwise tend to fly apart due to the electromagnetic force (like charges repulse).
The electrostatic force between two protons is a repulsive force, but its magnitude depends on how far apart the two particles are. The equation is F=kCq1q2/r2. In this equation, kC is Coulomb's constant (8.99*109N*m2/C2), q1 and q2 are the charges (in this case q1=q2=1.602*10-19C) and r is the distance between the two charges.
The electric change of protons in the nucleus is called electric force. It is form between the gravitation of two objects.
Between protons and electrons.
Protons are +1 charged and electrons are -1 charged. This is an electric force
The strong nuclear force, aka the strong interaction.
strong nuclear force which acts between all nucleons keeps them together
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.
The strong force holds the nucleus together against the repulsion between the electric charges of the protons.
Two main forces act in an atom, the electromagnetic force and the strong force. The electromagnetic force pulls the nucleus apart, while the strong force holds it together. Both neutrons and protons contribute to the strong force, but only protons contribute to the electromagnetic force. If an atom has too many protons and not enough neutrons, the electromagnetic force will overpower the strong force, and the nucleus will rip apart into more stable forms.
weaker as square of distance
Answer this What is the electric force acting between two charges of 0.0042 C and −0.0050 C that are 0.0030 m apart question…
The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.The so-called "strong force". It is, precisely, a force between nucleons (protons and neutrons), acts only at very short distances, and is a different force from the better-known electric, magnetic and gravitational forces.