An electron and a proton are fixed at a separation distance of 879 nm. Find the...

A proton and an electron are fixed in space with a separation of 837 nm. Calculate...

A proton and an electron are fixed in space with a separation of 837 nm. Calculate the electric potential at the midpoint between the two particles. potential: V Find the magnitude of the electric field at the same point. magnitude of field: N/C The direction of field is toward the proton. toward the electron. another direction. undetermined.

A proton and an electron are fixed in space with a separation of 947 nm. Calculate...

A proton and an electron are fixed in space with a separation of 947 nm. Calculate the electric potential at the midpoint between the two particles. Find the magnitude and direction of the electric field at the same point. Potential: _____V Magnitude of field: ______N/C Direction of field: (a) toward the proton (b) toward the electron (c) another direction (d) undetermined

A proton and electron are separated by 3.5 nm. (Note: ke=8.99x109N.m2/C2) (a) What is the magnitude...

A proton and electron are separated by 3.5 nm. (Note: ke=8.99x109N.m2/C2) (a) What is the magnitude of the force on the electron? (b) What is the magnitude of the force on the proton? (c) What is the electric field of the proton at the electron position?

A dipole consisting of a protons and an electron held a distance d apart is aligned...

A dipole consisting of a protons and an electron held a distance d apart is aligned along a z axis. A second proton is then placed at the midpoint of the line joining the electron and proton of the dipole. What is the ratio of the electric field magnitude at (0, 0, 10d) to the electric field magnitude at (0, 0, 20d)?

A proton and an electron are moving due east in a constant electric field that also...

A proton and an electron are moving due east in a constant electric field that also points due east. The electric field has a magnitude of 8.0 × 104 N/C. Determine the magnitude of the acceleration of the proton and the electron.

A particular electric dipole consists of a proton of charge of 1.6x10-19 Coulomb and an electron...

A particular electric dipole consists of a proton of charge of 1.6x10-19 Coulomb and an electron of charge of -1.6x10-19 Coulomb, separated by 2x10-10[m] = 0.2[nm]. 1a. What’s the electrostatic force between the charges (magnitude and direction), and why? 1b. What’s the electric field magnitude and direction at a point halfway between the two charges, and why? 1c. How much energy (in electron Volts OR in Joules) is needed to separate these two charges?

a) Calculate the acceleration, magnitude and direction, of an electron and a proton individually when put...

a) Calculate the acceleration, magnitude and direction, of an electron and a proton individually when put a distance d = 9 nm away from an infinite line of charge with linear charge density λ = 5 ∗ 10^(−10) C/m b) Calculate the acceleration, magnitude and direction, of an electron and a proton individually when put a distance d = 9 nm away from an infinite sheet of charge with surface charge density σ = 5 ∗ 10^(−10) C/m^2

Two particles, an electron and a proton, are initially at rest in a uniform electric field...

Two particles, an electron and a proton, are initially at rest in a uniform electric field of magnitude 478 N/C. If the particles are free to move, what are their speeds (in m/s) after 52.0 ns? Give the speed of both the electron and proton.

if a proton is placed in a uniform electric field, and an electron is palced in...

if a proton is placed in a uniform electric field, and an electron is palced in another uniform electric field of the same wavelength, will the electron or the proton accerate more slowly? explain. what physics concept does this apply to

In Niels Bohr's 1913 model of the hydrogen atom, an electron circles the proton at a...

In Niels Bohr's 1913 model of the hydrogen atom, an electron circles the proton at a distance of 5.29 ✕ 10-11 m with a speed of 2.19 ✕ 106 m/s. Compute the magnitude of the magnetic field that this motion produces at the location of the proton.