A hydrogen atom is at the earth’s surface. The electron and proton in the atom are separated by a distance of 5.29×10?11m. What is the ratio of the magnitude of the electric force exerted by the proton on the electron to the weight of the electron?
A hydrogen atom is at the earth’s surface. The electron and proton in the atom are...
In the Bohr model of the Hydrogen atom, a single electron orbits around a single proton (which constitutes the nucleus). The mass of the electron (9.11x10-31 kg) is much less than the proton (1.67x10-27 kg), so the proton remains stationary while the electron moves around it. If the electron is 6.6x10-11 m away from the proton, calculate the magnitude of the electric force (in N) exerted by the proton on the electron. b) [Continued ...] In the Bohr model, an...
In the bohr model of the hydrogen atom the electron is in a circular orbit of r = 5.29 x 10^-11m around the nuclear proton. The mass of the electron is 9.11 x 10^ -31 kg. Find the speed of the electron. Hint: use Coulomb’s law and the concept of the force for an object going in a circular motion.
Determine the magnitude and direction of the electric force on the electron of a hydrogen atom exerted by the single proton that is the atom’s nucleus. Assume the average distance between the revolving electron and a proton is r= 0.53×10^-10m.
The electron and the proton in a hydrogen atom are about 10−10m from each other. Determine the magnitude of the electric force exerted on an electron.
The electron and the proton in a hydrogen atom have equal and opposite charges at adistance of 5.3×10−11m. What would be the mass of two particles with the samecharges as a proton and electron so that the gravitational force would be the samemagnitude as the electric force at this distance? Assume the two masses are the same. I know the correct answer is 2x10^-9 but can you please show my why in the simplest way including the formula you are...
Example 15.1 The Forces in a Hydrogen Atom Goal Contrast the magnitudes of an electric force and a gravitational force. Problem The electron and proton of a hydrogen atom are separated (on the average) by a distance of about 5.30 x 1011 m. Find the magnitudes of the electric force and the gravitational force that each particle exerts on the other, and the ratio of the electric force, Fe, to the gravitational force, Fo Strategy Solving this problem is just...
Assuming that the average distance between the electron and the proton in a hydrogen atom is 1.0 angstrom, what is the average force exerted by the proton on the electron?
Also in the hydrogen atom, what is the force exerted by the electron on the proton? If you get the same magnitude for the force as in question 1, could you then conclude (by Newton’s Second Law) that the proton and electron experience the same (centripetal) acceleration magnitude? Why or why not
A muonic hydrogen atom is a proton orbited by a muon (a particle with the same charge as an electron and 207 times its mass) in which the mass of the muon is significant relative to the mass of the proton. What would be the radius of the smallest muon orbit in a muonic hydrogen atom? a. 1.10 x 10^-8m b. 2.56 x 10^-13m c. 5.29 x 10^-11m d. 2.84 x 10^-13m e. 1.03 x 10^-8m
1. In the Bohr model of the hydrogen atom, a single electron orbits a single proton at a distance r-0.50 x 10-10 meters as shown. a) b Assuming the Coulomb force supplies the necessary centripetal force, find the Find the value of the attractive Coulomb force exerted on the electron. electron's speed v in its orbit about the nucleus. Can a charged object exert forces on an uncharged object? If so, will this force be attractive, repulsive, or is either...