Here, we can use the following equation
F = kq1q2 / r2
where q1 and q2 are charges and r is the distance between two charges
F = 9e9 * 1.6e-19 * 1.6e-19 / (5.29e-11)2
F = 8.233e-8 N
Question 5: What is the magnitude of the coulomb force between the proton and eleetron in...
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.
Question 3: In a hydrogen atom, the electron is at a distance of 5 x 10-11 m from the nucleus, which consists of a proton. Find the force between the electron and the proton.
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?
r-529 x1σ11 m Mp= 1.67×10 -27 kg /n-911 × 10-31 kg
Say you have a point charge of one Coulomb and a hydrogen atom some distance away. Within what distance would the difference of forces on the proton and electron from the Coulomb charge exceed the attraction between the proton and electron that holds the hydrogen atom together. Treat the hydrogen atom as a proton and electron 0.53 × 10−10 m (a.k.a., one Bohr radius) apart
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...
In the Rutherford model of the hydrogen atom, a proton (mass M, charge ) is the nucleus and an electron (mass m, charge ) moves around the proton in a circle of radius r. Let k denote the Coulomb force constant (1/40) and the universal gravitational constant. The ratio of the electrostatic force to the gravitational force between electron and proton is: Select one a. kOq/GMm b. Og/GMora C. GM/ d. k Mm/GO e. GOg/kM
What is the magnitude of the electrostatic force on one proton due to an electron at a typical distance of 10^-10 m apart?
In the Rutherford model of the hydrogen atom, a proton (mass M, charge ) is the nucleus and an electron (mass m, charge g) moves around the proton in a circle of radius r. Let k denote the Coulomb force constant (1/472) and the universal gravitational constant. The ratio of the electrostatic force to the gravitational force between electron and proton is: Select one: O a. GMm/kQq O b. kQqGM2 O c. kg/GM O d. GOq/k Mon O e. kMme
In the Rutherford model of the hydrogen atom, a proton (mass M, charge Q) is the nucleus and an electron (mass m, charge q) moves around the proton in a circle of radius r. Let k denote the Coulomb force constant (1/4peo) and G the universal gravitational constant. The ratio of the electrostatic force to the gravitational force between electron and proton is: Select one: a. kMm/ GQq b.kQq/GMm c. GQq/kMm d. kQq/GMmr2 e. GMm/kQq
What is the magnitude of the electric force (in mN) of attraction between an atom's nucleus (q=+41-e) and its innermost electron if the distance between them is 2.37×10−12-m?