Let 15.0 eV electrons approach a potential barrier of height 4.0 eV. (a) For what minimum...

Suppose a beam of 4.00 eV protons strikes a potential energy barrier of height 6.20 eV...

Suppose a beam of 4.00 eV protons strikes a potential energy barrier of height 6.20 eV and thickness 0.560 nm, at a rate equivalent to a current of 1150 A. (a) How many years would you have to wait (on average) for one proton to be transmitted through the barrier? (b) How long would you have to wait if the beam consisted of electrons rather than protons?

Suppose a beam of 5.10 eV protons strikes a potential energy barrier of height 5.80 eV...

Suppose a beam of 5.10 eV protons strikes a potential energy barrier of height 5.80 eV and thickness 0.810 nm, at a rate equivalent to a current of 980 A. (a) How many years would you have to wait (on average) for one proton to be transmitted through the barrier? (b) How long would you have to wait if the beam consisted of electrons rather than protons?

Suppose a beam of 4.60 eV protons strikes a potential energy barrier of height 6.10 eV...

Suppose a beam of 4.60 eV protons strikes a potential energy barrier of height 6.10 eV and thickness 0.530 nm, at a rate equivalent to a current of 1190 A. (a) How many years would you have to wait (on average) for one proton to be transmitted through the barrier? (b) How long would you have to wait if the beam consisted of electrons rather than protons?

Suppose a beam of 5.10 eV protons strikes a potential energy barrier of height 6.00 eV...

Suppose a beam of 5.10 eV protons strikes a potential energy barrier of height 6.00 eV and thickness 0.840 nm, at a rate equivalent to a current of 860 A. (a) How many years would you have to wait (on average) for one proton to be transmitted through the barrier? (b) How long would you have to wait if the beam consisted of electrons rather than protons?

An electron with an energy of 5.5 eV approaches a potential barrier of height 6.1 eV...

An electron with an energy of 5.5 eV approaches a potential barrier of height 6.1 eV and thickness of 1nm. What is the relative probability that the electron passes through the barrier? What barrier height should be used to decrease the relative probability by a factor of 100?

A beam of electrons with kinetic energy 25 eV encounter a potential barrier of height 20...

A beam of electrons with kinetic energy 25 eV encounter a potential barrier of height 20 eV. Some electrons reflect from the barrier, and some are transmitted. Find the wave number k of the transmitted electrons. You can take U = 0 for x < 0, and U = 15 eV for x > 0

A beam of 1,000,000 electrons, each with kinetic energy E = 1.0 eV, is incident on...

A beam of 1,000,000 electrons, each with kinetic energy E = 1.0 eV, is incident on a potential barrier with the height V0 = 7.0 eV. (a) How many electrons in the beam will be transmitted through the barrier if the barrier width a = 0.25 nm? (b) Answer the same question if the width is doubled, that is, a = 0.5 nm. (c) Briefly explain the effect of the barrier width in quantum tunneling, based on your results in...

A square barrier of height Vo = 5.0 eV and width of a = 1.0nm has...

A square barrier of height Vo = 5.0 eV and width of a = 1.0nm has a beam of electrons incident on it having kinetic energy E = 4.0 eV. The wave function for x less than or equal to 0 can be written, Psi1 = Aeik1x + Be-ik1x and for the region inside the barrier, the wave function can be written Psi2 = Cek2x + Dek2x. Determine the equations describing the continuity conditions at x=0.

Electrons are fired at a rectangular potential energy barrier, once every 245 ms. If the barrier...

Electrons are fired at a rectangular potential energy barrier, once every 245 ms. If the barrier is 2.55 nm thick and has a height that exceeds the energy of the incident electrons by exactly 612 meV, how long on average would you expect to wait for one electron to pass through the barrier?.

a) A photoelectric surface has a work function of 2.75 eV. What is the minimum frequency...

a) A photoelectric surface has a work function of 2.75 eV. What is the minimum frequency of light that will cause photoelectron emission from this surface ? answer in the format of a.bc x 10de Hz b) A photoelectric cell is illuminated with white light (wavelengths from 400 nm to 700 nm). What is the maximum kinetic energy (in eV) of the electrons emitted by this surface if its work function is 2.30 eV ? 4 digit answer