The Wavelike Properties of Particles

1
Chapter 5

• The Wavelike Properties of Particles

2
The Wavelike Properties of Particles

• The de Broglie Hypothesis
• Measurements of Particles Wavelengths
• Wave Packets
• The Probabilistic Interpretation of the Wave
  Function
• The Uncertainty Principle
• Some Consequences of Uncertainty Principle
• Wave-Particle Duality

3
The de Broglie Hypothesis

• As it was showed by Thomson the rays of a
  cathode tube can be deflected by electric and
  magnetic fields and therefore must consist of
  electrically charged particles.
• Thomson showed that all the particles have the
  same charge-to-mass ratio q/m. He also showed
  that particles with this charge-to-mass ratios
  can be obtained using any materials for the
  cathode, which means that these particles, now
  called electrons, are a fundamental constituent
  of matter.

4
The de Broglie Hypothesis

• Since light seems to have both wave and
  particle properties, it is natural to ask whether
  matter (electrons, protons) might also have both
  wave and particle characteristics.
• In 1924, a French physics student, Louis de
  Broglie, suggested this idea in his doctoral
  dissertation.
• For the wavelength of electron, de Broglie
  chose
• ? h/p
• f E/h
• where E is the total energy, p is the momentum,
  and
• ? is called the de Broglie wavelength of the
  particle.

5
The de Broglie Hypothesis

• For photons these same equations results
  directly from Einsteins quantization of
  radiation E hf and equation for an energy of a
  photon with zero rest energy E pc
• E pc hf hc/?
• Using relativistic mechanics de Broglie
  demonstrated, that this equation can also be
  applied to particles with mass and used them to
  physical interpretation of Bohrs hydrogen-like
  atom.

6
The de Broglie Wavelength

• Using de Broglie relation lets find the
  wavelength of a 10-6g particle moving with a
  speed 10-6m/s

Since the wavelength found in this example is so
small, much smaller than any possible apertures,
diffraction or interference of such waves can not
be observed.
7
The de Broglie Wavelength

• The situation are different for low energy
  electrons and other microscopic particles.
• Consider a particle with kinetic energy K. Its
  momentum is found from

Its wavelength is than
8
The de Broglie Wavelength

If we multiply the numerator and denominator by c
we obtain
Where mc20.511MeV for electrons, and K in
electronvolts.
9
The de Broglie Wavelength
We obtained the electron wavelength

Similarly, for proton (mc2 938 MeV for protons)
10
The de Broglie Wavelength
For the molecules of a stationary gas at the
absolute temperature T, the square average speed
of the molecule v2 is determined by Maxwells Law
Than the momentum of the molecule is
Knowing that the mass of He atom, for instance,
is 6.7x10-24g, (kB1.38x10-23J/K) we obtain for
He wavelength
11
The de Broglie Wavelength
Similarly, for the molecule of hydrogen

• .

and for the thermal neutrons
This calculations show, that for the accelerated
electrons, for atoms of helium, hydrogen
molecules under the room temperature, for thermal
neutrons and other slow light particles de
Broglie wavelength is on the same order as for
soft X-rays. So, we can expect, that diffraction
can be observed for this particles
12

• Show that the wavelength of a nonrelativistic
  neutron is
• where Kn is the kinetic energy of the neutron in
  electron-volts. (b) What is the wavelength of a
  1.00-keV neutron?

13

• Show that the wavelength of a nonrelativistic
  neutron is
• where Kn is the kinetic energy of the neutron in
  electron-volts. (b) What is the wavelength of a
  1.00-keV neutron?

Kinetic energy, K, in this equation is in Joules
(a)
14

• Show that the wavelength of a nonrelativistic
  neutron is
• where Kn is the kinetic energy of the neutron in
  electron-volts. (b) What is the wavelength of a
  1.00-keV neutron?

(b)
15

• The nucleus of an atom is on the order of 1014
  m in diameter. For an electron to be confined to
  a nucleus, its de Broglie wavelength would have
  to be on this order of magnitude or smaller. (a)
  What would be the kinetic energy of an electron
  confined to this region? (b) Given that typical
  binding energies of electrons in atoms are
  measured to be on the order of a few eV, would
  you expect to find an electron in a nucleus?

16

• The nucleus of an atom is on the order of 1014
  m in diameter. For an electron to be confined to
  a nucleus, its de Broglie wavelength would have
  to be on this order of magnitude or smaller. (a)
  What would be the kinetic energy of an electron
  confined to this region? (b) Given that typical
  binding energies of electrons in atoms are
  measured to be on the order of a few eV, would
  you expect to find an electron in a nucleus?

(a)
17

• The nucleus of an atom is on the order of 1014
  m in diameter. For an electron to be confined to
  a nucleus, its de Broglie wavelength would have
  to be on this order of magnitude or smaller. (a)
  What would be the kinetic energy of an electron
  confined to this region? (b) Given that typical
  binding energies of electrons in atoms are
  measured to be on the order of a few eV, would
  you expect to find an electron in a nucleus?

,
(b)
With its
18
Electron Interference and Diffraction

• The electron wave interference was
  discovered in 1927 by C.J. Davisson and
  L.H.Germer as they were studying electron
  scattering from a nickel target at the Bell
  Telephone Laboratories.
• After heating the target to remove an oxide
  coating that had accumulate after accidental
  break in the vacuum system, they found that the
  scattered electron intensity is a function of the
  scattered angle and show maxima and minima. Their
  target had crystallized during the heating, and
  by accident they had observed electron
  diffraction.
• Then Davisson and Germer prepared a target
  from a single crystal of nickel and investigated
  this phenomenon.

19

• The Davisson-Germer experiment.
• Low energy electrons scattered at angle F from
  a nickel crystal are detected in an ionization
  chamber. The kinetic energy of electrons could be
  varied by changing the accelerating voltage on
  the electron gun.

20

• Scattered intensity vs detector angle for 54-ev
  electrons. Polar plot of the data. The intensity
  at each angle is indicated by the distance of the
  point from the origin. Scattered angle F is
  plotted clockwise started at the vertical axis.

21

• The same data plotted on a Cartesian graph. The
  intensity scale are the same on the both graphs.
  In each plot there is maximum intensity at F50º,
  as predicted for Bragg scattering of waves having
  wavelength ? h/p.

22

• Scattering of electron by crystal. Electron
  waves are strongly scattered if the Bragg
  condition n? D SinF is met.

23

• Test of the de Broglie formula ? h/p. The
  wavelength is computed from a plot of the
  diffraction data plotted against V0-1/2, where V0
  is the accelerating voltage. The straight line is
  1.226V0-1/2 nm as predicted from ? h/(2mE)-1/2

24

• Test of the de Broglie formula ? h/p. The
  wavelength is computed from a plot of the
  diffraction data plotted against V0-1/2, where V0
  is the accelerating voltage. The straight line is
  1.226V0-1/2 nm as predicted from ? h/(2mE)-1/2

25

• A series of a polar graphs of Davisson and
  Germers data at electron accelerating potential
  from 36 V to 68 V. Note the development of the
  peak at F 50º to a maximum when V0 54 V.

26

• Variation of the scattered electron intensity
  with wavelength for constant F. The incident beam
  in this case was 10º from the normal, the
  resulting diffraction causing the measured peaks
  to be slightly shifted from the positions
  computed from n? D Sin F.

27

• Schematic arrangement used for producing a
  diffraction pattern from a polycrystalline
  aluminum target.

28

• Diffraction pattern produced by x-rays of
  wavelength 0.071 nm and an aluminum foil target.

29

• Diffraction pattern produced by 600-eV electrons
  and an aluminum foil target ( de Broigle
  wavelength of about 0.05 nm )

30

• Diffraction pattern produced by 600-eV electrons
  and an aluminum foil target ( de Broigle
  wavelength of about 0.05 nm ) .

31

• Diffraction pattern produced by 0.0568-eV
  neutrons (de Broglie wavelength of 0.120 nm) and
  a target of polycrystalline copper. Note the
  similarity in the pattern produced by x-rays,
  electrons, and neutrons.

32

• Diffraction pattern produced by 0.0568-eV
  neutrons (de Broglie wavelength of 0.120 nm) and
  a target of polycrystalline copper. Note the
  similarity in the pattern produced by x-rays,
  electrons, and neutrons.

33

• In the DavissonGermer experiment, 54.0-eV
  electrons were diffracted from a nickel lattice.
  If the first maximum in the diffraction pattern
  was observed at f 50.0, what was the lattice
  spacing a between the vertical rows of atoms in
  the figure? (It is not the same as the spacing
  between the horizontal rows of atoms.)

34

• In the DavissonGermer experiment, 54.0-eV
  electrons were diffracted from a nickel lattice.
  If the first maximum in the diffraction pattern
  was observed at f 50.0, what was the lattice
  spacing a between the vertical rows of atoms in
  the figure? (It is not the same as the spacing
  between the horizontal rows of atoms.)

35

• In the DavissonGermer experiment, 54.0-eV
  electrons were diffracted from a nickel lattice.
  If the first maximum in the diffraction pattern
  was observed at f 50.0, what was the lattice
  spacing a between the vertical rows of atoms in
  the figure? (It is not the same as the spacing
  between the horizontal rows of atoms.)

36

• A photon has an energy equal to the kinetic
  energy of a particle moving with a speed of
  0.900c. (a) Calculate the ratio of the wavelength
  of the photon to the wavelength of the particle.
  (b) What would this ratio be for a particle
  having a speed of 0.00100c ? (c) What value does
  the ratio of the two wavelengths approach at high
  particle speeds?(d) At low particle speeds?

37

• A photon has an energy equal to the kinetic
  energy of a particle moving with a speed of
  0.900c. (a) Calculate the ratio of the wavelength
  of the photon to the wavelength of the particle.
  (b) What would this ratio be for a particle
  having a speed of 0.00100c ? (c) What value does
  the ratio of the two wavelengths approach at high
  particle speeds? (d) At low particle speeds?

For a particle
For a photon
38

• A photon has an energy equal to the kinetic
  energy of a particle moving with a speed of
  0.900c. (a) Calculate the ratio of the wavelength
  of the photon to the wavelength of the particle.
  (b) What would this ratio be for a particle
  having a speed of 0.00100c ? (c) What value does
  the ratio of the two wavelengths approach at high
  particle speeds?(d) At low particle speeds?

(a)
(b)
39

• A photon has an energy equal to the kinetic
  energy of a particle moving with a speed of
  0.900c. (a) Calculate the ratio of the wavelength
  of the photon to the wavelength of the particle.
  (b) What would this ratio be for a particle
  having a speed of 0.00100c ? (c) What value does
  the ratio of the two wavelengths approach at high
  particle speeds?(d) At low particle speeds?

As
(c)
becomes nearly equal to ?.
and
,
(d)
40
What is waving? For matter it is the
probability of finding the particle that waves.
Classical waves are the solution of the classical
wave equation
Harmonic waves of amplitude y0, frequency f and
period T where the angular frequency ? and the
wave number k are defined by and the wave or
phase velocity vp is given by
41

• If the film were to be observed at various
  stages, such
• as after being struck by 28 electrons the
  pattern of individually exposed grains will be
  similar to shown here.

42

• After exposure by about 1000 electrons the
  pattern will be similar to this.

43

• And again for exposure of about 10,000
  electrons we will obtained a pattern like this.

44

• Two source interference pattern. If the sources
  are coherent and in phase, the waves from the
  sources interfere constructively at points for
  which the path difference dsin? is an integer
  number of wavelength.

45

• Grows of two-slits interference pattern. The
  photo is an actual two-slit electron interference
  pattern in which the film was exposed to millions
  of electrons. The pattern is identical to that
  usually obtained with photons.

46

• Using relativistic mechanics, de Broglie was
  able to derive the physical interpretation of
  Bohrs quantization of the angular momentum of
  electron.
• He demonstrate that quantization of angular
  momentum of the electron in hydrogenlike atoms is
  equivalent to a standing wave condition
• 
  
• for n integer
• The idea of explaining discrete energy states
  in matter by standing waves thus seems quite
  promising.

47

• Standing waves around the circumference of a
  circle. In this case the circle is 3? in
  circumference. For example, if a steel ring had
  been suitable tapped with a hammer, the shape of
  the ring would oscillate between the extreme
  positions represented by the solid and broken
  lines.

48

• Wave pulse moving along a string. A pulse have a
  beginning and an end i.e. it is localized,
  unlike a pure harmonic wave, which goes on
  forever in space and time.

49

• Two waves of slightly different wavelength and
  frequency produced beats.

(a) Shows y(x) at given instant for each of the
two waves. The waves are in phase at the origin
but because of the difference in wavelength, they
become out of phase and then in phase again.
50
(b) The sum of these waves. The spatial extend of
the group ?x is inversely proportional to the
difference in wave numbers ?k, where k is
related to the wavelength by k 2p/?.
51
BEATS

• Consider two waves of equal amplitude and nearly
  equal frequencies and wavelengths.
• The sum of the two waves is (superposition)
• F(x) F1(x) F2(x) Fsin(k1x ?1t)sin(k2x
  ?2t)

52
BEATS

• F(x) F1(x) F2(x) Fsin(k1x ?1t)sin(k2x
  ?2t)
• using the trigonometric relation
• Sina Sinß 2Cos(a-ß)/2 Sin(aß)/2
• with a (k1x ?1t)
  
  
  
  
  
  
  ß (k2x ?2t), we get

53
BEATS

• with

54
BEATS

• This is an equivalent of an harmonic wave
• whose amplitude is modulated by
• We have formed wave packets of extend ?x and
  can imagine each wave packet representing a
  particle.

55

• Now
• The particle is in the region ?x, the momentum
  of the particle in the range ?k
• p ?k ? ?p ??k
• ?x ?p h - Uncertainty Principle
• In order to localize the particle within a
  region ?x, we need to relax the precision on the
  value of the momentum, ?p .

56

• Gaussian-shaped wave packets y(x) and the
  corresponding Gaussian distributions of wave
  numbers A(k). (a) A narrow packet. (b) A wide
  packet. The standard deviations in each case are
  related by sxsk ½.

57
Wave packet for which the group velocity is half
of phase velocity. Water waves whose wavelengths
are a few centimeters, but much less than the
water depth, have this property. The arrow
travels at the phase velocity, following a point
of constant phase for the dominant wavelength.
The cross at the center of the group travels at
the group velocity.
58

• A three-dimensional wave packet representing a
  particle moving along the x-axis. The dots
  indicate the position of classical particle. Note
  that the particle spreads out in the x and y
  directions. This spreading is due to dispersion ,
  resulting from the fact that the phase velocity
  of the individual wave making up the packet
  depends on the wavelength of the waves.

59

• Seeing an electron with a gamma-ray
  microscope.

60

• Because of the size of the lens, the momentum of
  the scattered photons is uncertain by ?px psin?
  hsin?/ ?. Thus the recoil momentum of the
  electron is also uncertain by at least this
  amount.

61

• The position of the electron can not be
  resolved better than the width of the central
  maximum of the diffraction pattern ?x
  ?/sin?. The product of the uncertainties ?px ?x
  is therefore of the order of Plancks constant h.

62
The Interpretation of the Wave Function

• Given that electrons have wave-like properties,
  it should be possible to produce standing
  electron waves. The energy is associated with the
  frequency of the standing wave, as E hf, so
  standing waves imply quantized energies.
• The idea that discrete energy states in atom can
  be explained by standing waves led to the
  development by Erwin Schrödinger in 1926
  mathematical theory known as quantum theory,
  quantum mechanics, or wave mechanics.
• In this theory electron is described by a wave
  function ? that obeys a wave equation called the
  Schrödinger equation.

63
The Interpretation of the Wave Function

• The form of the Schrödinger equation of a
  particular system depends on the forces acting on
  the particle, which are described by the
  potential energy functions associated with this
  forces.
• Schrödinger solved the standing wave problem
  for hydrogen atom, the simple harmonic
  oscillator, and other system of interest. He
  found that the allowed frequencies, combined with
  Ehf, resulted in the set of energy levels, found
  experimentally for the hydrogen atom.
• Quantum theory is the basis for our
  understanding of the modern world, from the inner
  working of the atomic nucleus to the radiation
  spectra of distant galaxies.

64
The Interpretation of the Wave Function

• The wave function for waves in a string is the
  string displacement y. The wave function for
  sound waves can be either the displacement of the
  air molecules, or the pressure P. The wave
  function of the electromagnetic waves is the
  electric field E and the magnetic field B.
• What is the wave function for the electron ??
  The Schrödinger equation describes a single
  particle. The square of the wave function for a
  particle describes the probability density, which
  is the probability per unit volume, of finding
  the particle at a location.

65
The Interpretation of the Wave Function

• The probability of finding the particle in
  some volume element must also be proportional to
  the size of volume element dV.
• Thus, in one dimension, the probability of
  finding a particle in a region dx at the position
  x is ?2(x)dx. If we call this probability P(x)dx,
  where P(x) is the probability density, we have
• P(x) ?2(x)
• The probability of finding the particle in
  dx at point x1 or point x2 is the sum of
  separate probabilities
• P(x1)dx P(x2)dx.
• If we have a particle at all the probability
  of finding a particle somewhere must be 1.

66
The Interpretation of the Wave Function

• Then, the sum of the probabilities over all the
  possible values of x must equal 1. That is,
• This equation is called the normalization
  condition. If ? is to satisfy the normalization
  condition, it must approach zero as x is approach
  infinity.

67
Probability Calculation for a Classical Particle

• It is known that a classical point particle
  moves back and forth with constant speed between
  two walls at x 0 and x 8cm. No additional
  information about of location of the particle is
  known.
• (a) What is the probability density P(x)?
• (b) What is the probability of finding the
  particle at x2cm?
• (c) What is the probability of finding the
  particle between x3.0 cm and x3.4 cm?

68
A Particle in a Box

• We can illustrate many of important features of
  quantum physics by considering of simple problem
  of particle of mass m confined to a
  one-dimensional box of length L.
• This can be considered as a crude description
  of an electron confined within an atom, or a
  proton confined within a nucleus.
• According to the quantum theory, the
  particle is described by the wave function ?,
  whose square describes the probability of finding
  the particle in some region. Since we are
  assuming that the particle is indeed inside the
  box, the wave function must be zero everywhere
  outside the box ? 0 for x0 and for xL.

69
A Particle in a Box

• The allowed wavelength for a particle in the
  box are those where the length L equals an
  integral number of half wavelengths.
• L n( ?n/2) n 1,2,3,.
• This is a standing wave condition for a
  particle in the box of length L.
• The total energy of the particle is its
  kinetic energy
• E (1/2)mv2 p2/2m
• Substituting the de Broglie relation pn
  h/?n,

70
A Particle in a Box

• Then the standing wave condition ?n 2L/n gives
  the allowed energies
• where

71
A Particle in a Box

• The equation
• gives the allowed energies for a particle in the
  box.
• This is the ground state energy for a particle
  in the box, which is the energy of the lowest
  state.

72
A Particle in a Box

• The condition that we used for the wave function
  in the box
• ? 0 at x 0 and x L
• is called the boundary condition.
• The boundary conditions in quantum theory lead
  to energy quantization.
• Note, that the lowest energy for a particle in
  the box is not zero. The result is a general
  feature of quantum theory.
• If a particle is confined to some region of
  space, the particle has a minimum kinetic
  energy, which is called zero-point energy. The
  smaller the region of space the particle is
  confined to, the greater its zero-point energy.

73
A Particle in a Box

• If an electron is confined (i.e., bond to an
  atom) in some energy state Ei, the electron can
  make a transition to another energy state Ef with
  the emission of photon. The frequency of the
  emitted photon is found from the conservation of
  the energy
• hf Ei Ef
• The wavelength of the photon is then
• ? c/f hc/(Ei Ef)

74
Standing Wave Function

• The amplitude of a vibrating string fixed at x0
  and xL is given as
• where An is a constant and is the wave number.
• The wave function for a particle in a box are
  the same
• Using , we have

75
Standing Wave Function

• The wave function can thus be written

The constant An is determined by normalization
condition The result of evaluating the
integral and solving for An is
independent from n. The normalized wave function
for a particle in a box are thus
76
Graph of energy vs. x for a particle in the box,
that we also call an infinitely deep well. The
set of allowed values for the particles total
energy En is E1(n1), 4E1(n2), 9E1(n3) ..
77
Wave functions ?n(x) and probability densities
Pn(x) ?n2(x) for n1, 2, and 3 for the infinity
square well potential.
78
Probability distribution for n10 for the
infinity square well potential. The dashed line
is the classical probability density P1/L, which
is equal to the quantum mechanical distribution
averaged over a region ?x containing several
oscillations. A physical measurement with
resolution ?x will yield the classical result if
n is so large that ?2(x) has many oscillations in
?x.
79
Photon Emission by Particle in a Box

• An electron is in one dimensional box of length
  0.1nm. (a) Find the ground state energy. (b) Find
  the energy in electron-volts of the five lowest
  states, and then sketch an energy level diagram.
  (c) Find the wavelength of the photon emitted for
  each transition from the state n3 to a
  lower-energy state.

80
(No Transcript)
81
The probability of a particle being found in a
specified region of a box.

• The particle in one-dimensional box of length L
  is in the ground state. Find the probability of
  finding the particle (a) anywhere in a region of
  length ?x 0.01L, centered at x ½L (b) in
  the region 0ltxlt(1/4)L.

82
Expectation Values

• The most that we can know about the position of
  the particle is the probability of measuring a
  certain value of this position x. If we measure
  the position for a large number of identical
  systems, we get a range of values corresponding
  to the probability distribution.
• The average value of x obtained from such
  measurements is called the expectation value and
  written x. The expectation value of x is the
  same as the average value of x that we would
  expect to obtain from a measurement of the
  position of a large number of particles with the
  same wave function ?(x).

83
Expectation Values

• Since ?2(x)dx is the probability of finding a
  particle in the region dx, the expectation value
  of x is
• The expectation value of any function f(x) is
  given by

84
Calculating expectation values

• Find (a) x and (b) x2 for a particle in
  its ground state in a box of length L.

85
Complex Numbers

• A complex number has the form aib, with i2-1 or
  iv-1 imaginary unit.
• a - real part b imaginary part i imaginary
  unit
• (a ib) (c id) (ac) i(bd)
• m(a ib) ma imb
• (a ib) (c id) (ac - bd) i(ad bc)
• The absolute value of a ib is denoted by aib
  and is given by aib v a2 b2

86
Complex Numbers

• The complex conjugate of aib is denoted by
  (aib) and is given
• (aib) (a-ib)
• Then
• (aib) (aib) (a-ib) (aib)a2 b2

87
Polar Form of Complex Numbers

• p v a2 b2 a ib
• We can represent the number (a ib) in the
  complex xy plane.
• Then the polar coordinates
• a ib p(cosf isinf)
• Remembering the Euler formula
• eif (cosfisinf)
• a ib p eif

Imaginary axis
p
b
f
Real axis
a
Euler Identities eif cosf isinf e-if
cosf - isinf where i v-1
88
Fourier Transform

• In quantum mechanics, our basic function is the
  pure sinusoidal plane wave describing a free
  particle, given in equation
• We are not interest here in how things behave
  in time, so we chose a convenient time of zero.
  Thus, our building block is
• Now we claim that any general, nonperiodic wave
  function ?(x) can be expressed as a sum/integral
  of this building blocks over the continuum of
  wave numbers

89
Fourier Transform
The amplitude A(k) of the plane wave is naturally
a function of k, it tell us how much of each
different wave number goes into the sum. Although
we cant pull it out of the integral, the
equation can be solved for A(k). The result is
The proper name of for A(k) is the Fourier
transform of the function ?(x).
90

• 1 xlt a
• 0 xgt a
• Let use Euler identities _eika cosfisinf
• e-ika cosf-isinf
• eika- e-ika 2isinka
• And we can overwrite the equation for A(k)

?(x)
91
General Wave Packets

• Any point in space can be described as a linear
  combination of unit vectors. The three unit
  vectors î, j, and constitute a base that can
  generate any points in space.
• In similar way given a periodic function, any
  value that the function can take, can be produced
  by the linear combination of a set of basic
  functions. The basic functions are the harmonic
  functions (sin or cos). The set of basic function
  is actually infinite.

92
The General Wave Packet

• A periodic function f(x) can be represented by
  the sum of harmonic waves
• y(x,t) S Aicos(kix ?it) Bisin(kix ?it)
• Ai and Bi amplitudes of the waves with wave
  number ki and angular frequency ?i.
• For a function that is not periodic there is an
  equivalent approach called Fourier
  Transformation.

93
Fourier Transformation

• A function F(x) that is not periodic can be
  represented by
• a sum (integral) of functions of the type
• eika CosfiSinf
• In math terms it called Fourier Transformation.
  Given a function F(x)
• where
• f(kj) represents the amplitude of base function
  e-ikx used to represent F(x).

94
The Schrödinger Equation

• The wave equation governing the motion of
  electron and other particles with mass m, which
  is analogous to the classical wave equation
• was found by Schrödinger in 1925 and is now known
  as the Schrödinger equation.

95
The Schrödinger Equation

• Like the classical wave equation, the
  Schrödinger equation is a partial differential
  equation in space and time.
• Like Newtons laws of motion, the Schrödinger
  equation cannot be derived. Its validity, like
  that of Newtons laws, lies in its agreement with
  experiment.

96

• We will start from classical description of the
  total energy of a particle
• Schrödinger converted this equation into a wave
  equation by defining a wavefunction, ?. He
  multiplied each factor in energy equation with
  that wave function

97

• To incorporate the de Broglie wavelength of the
  particle he introduced the operator,
  ,which provides the square of the momentum when
  applied to a plane wave

If we apply the operator to that wavefunction
where k is the wavenumber, which equals 2p/?. We
now simple replace the p2 in equation for energy
98
Time Independent Schrödinger Equation

• This equation is called time-independent
  Schrödinger equation.
• E is the total energy of the particle.
• The normalization condition now becomes
• ? ?(x)?(x)dx 1

99
A Solution to the Srödinger Equation

• Show that for a free particle of mass m moving
  in one dimension the function
• is a solution of the time independent Srödinger
  Equation for any values of the constants A and B.

100
Energy Quantization in Different Systems

• The quantized energies of a system are generally
  determined by solving the Schrödinger equation
  for that system. The form of the Schrödinger
  equation depends on the potential energy of the
  particle.

The potential energy for a one-dimensional box
from x 0 to x L is shown in Figure. This
potential energy function is called an infinity
square-well potential, and is described by U(x)
0, 0ltxltL U(x) 8, xlt0 or xgtL
101

• A Particle in Infinity Square Well Potential
• Inside the box U(x) 0, so the Schrödinger
  equation is written
• where E h? is the energy of the particle, or
• where k2 2mE/h2
• The general solution of this equation can be
  written as
• ?(x) A sin kx B cos kx
• where A and B are constants. At x0, we have
• ?(0) A sin (k0) B cos (0x) 0 B

102

• A Particle in Infinity Square Well Potential
• The boundary condition ?(x)0 at x0 thus gives
  B0 and equation becomes
• ?(x) A sin kx
• We received a sin wave with the wavelength ?
  related to wave number k in a usual way, ?
  2p/k. The boundary condition ?(x) 0 at xL gives
• ?(L) A sin kL 0
• This condition is satisfied if kL is any integer
  times p, or
• kn np / L
• If we will write the wave number k in terms of
  wavelength ? 2p/k, we will receive
  the standing wave condition for particle in the
  box
• n? / 2 L n 1,2,3,

103

• A Particle in Infinity Square Well Potential
• Solving k2 2mE/h2 for E and using the
  standing wave condition k np / L gives us the
  allowed energy values
• where
• For each value n, there is a wave function ?n(x)
  given by

104

• A Particle in Infinity Square Well Potential
• Compare with the equation we received for
  particle in the box, using the standing wave
  fitting with the constant An v2/L determined by
  normalization

Although this problem seems artificial, actually
it is useful for some physical problems, such as
a neutron inside the nucleus.
105
A Particle in a Finite Square Well
This potential energy function is described
mathematically by U(x)V0, xlt0 U(x)0,
0ltxltL U(x)V0, xgtL Here we assume that 0 EV0.
Inside the well, U(x)0, and the time independent
Schrödinger equation is the same as for the
infinite well

106
A Particle in a Finite Square Well

• or
• where k2 2mE/h2. The general solution is
• ?(x) A sin kx B cos kx
• but in this case, ?(x) is not required to be
  zero at x0, so B is not zero.

107
A Particle in a Finite Square Well

• Outside the well, the time independent
  Schrödinger equation is
• or
• where

108
The Harmonic Oscillator

• More realistic than a particle in a box is the
  harmonic oscillator, which applies to an object
  of mass m on a spring of force constant k or to
  any systems undergoing small oscillations about a
  stable equilibrium. The potential energy function
  for a such oscillator is
• where ?0 vk/m2pf is the angular frequency of
  the oscillator. Classically, the object
  oscillates between x A and x-A. Its total
  energy is
• which can have any nonnegative value, including
  zero.

109

• Potential energy function for a simple harmonic
  oscillator. Classically, the particle with energy
  E is confined between the turning points A and
  A.

110
The Harmonic Oscillator

• Classically, the probability of finding the
  particle in dx is proportional to the time spent
  in dx, which is dx/v. The speed of the particle
  can be obtained from the conservation of energy
  
• The classical probability is thus

111
The Harmonic Oscillator

• The classical probability is

Any values of the energy E is possible. The
lowest energy is E0, in which case the particle
is in the rest at the origin. The Shrödinger
equation for this problem is
112
The Harmonic Oscillator

• In quantum theory, the particle is represented
  by the wave function ?(x), which is determined by
  solving the Schrödinger equation for this
  potential.
• Only certain values of E will lead to solution
  that are well behaved, i.e., which approach zero
  as x approach infinity. Normalizeable wave
  function ?n(x) occur only for discrete values of
  the energy En given by
• where f0?0/2p is the classical frequency of the
  oscillator.

113
The Harmonic Oscillator

• where f0?0/2p is the classical frequency of the
  oscillator. Thus, the ground-state energy is ½h?
  and the exited energy levels are equally spaced
  by h?.

114
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115

• Energy levels in the simple harmonic oscillator
  potential. Transitions obeying the selection rule
  ?n1 are indicated by the arrows. Since the
  levels have equal spacing, the same energy h? is
  emitted or absorbed in all allowed transitions.
  For this special potential, the frequency of
  emitted or absorbed photon equals the frequency
  of oscillation, as predicted by classical theory.
  

116
The Harmonic Oscillator

• Compare this with uneven spacing of the energy
  levels for the particle in a box. If a harmonic
  oscillator makes a transition from energy level n
  to the next lowest energy level (n-1), the
  frequency f of the photon emitted is given by hf
  Ef Ei. Applying this equation gives
• The frequency f of the emitted photon is
  therefore equal to the classical frequency f0 of
  the oscillator.

117
Wave function for the ground state and the first
two excited states of the simple harmonic
oscillator potential, the states with n0, 1, and
2.
118
Probability density for the simple harmonic
oscillator plotted against the dimensionless
value , for n0, 1, and 2. The
blue curves are the classical probability
densities for the same energy, and the vertical
lines indicate the classical turning points x A
119

• Molecules vibrate as harmonic oscillators.
  Measuring vibration frequencies enables
  determination of force constants, bond strengths,
  and properties of solids.

120

• Verify that , where a
  is a positive constant, is a solution of the
  Schrödinger equation for the harmonic oscillator

121
Operators

• As we have seen, for a particle in a state of
  definite energy the probability distribution is
  independent of time. The expectation value of x
  is then given by
• In general, the expectation value of any
  function f(x) is given by

122
Operators

• If we know the momentum p of the particle as
  function of x, we can calculate the expectation
  value p. However, it is impossible in principle
  to find p as function of x since, according to
  uncertainty principle, both p and x can not be
  determined at the same time.
• To find p we need to know the distribution
  function for momentum. If we know ?(x), the
  distribution function can be found by Fourier
  analysis. It can be shown that p can be found
  from

123
Operators

• Similarly, p2 can be found from
• Notice that in computing the expectation value
  the operator representing the physical quantity
  operates on ?(x), not on ?(x). This is not
  important to the outcome when the operator is
  simply some function of x, but it is critical
  when the operator includes a differentiation, as
  in the case of momentum operator.

124
Expectation Values for p and p2

• Find p and p2 for the ground state wave
  function of the infinity square well.

125

• In classical mechanics, the total energy written
  in terms of position and momentum variables is
  called the Hamiltonian function

If we replace the momentum by the momentum
operator pop and note that U U(x), we obtain
the Hamiltonian operator Hop
The time-independent Schrödinger equation can
then be written
126
The advantage of writing the Schrödinger equation
in this formal way is that it allows for easy
generalization to more complicated problems such
as those with several particles moving in three
dimensions. We simply write the total energy of
the system in terms of position and momentum and
replace the momentum variables by the appropriate
operators to obtain the Hamiltonian operator for
the system.
127
Symbol Physical quantity Operator
f(x) Any function of x (the position, x the potential energy U(x), etc. f(x)
px x component of momentum
py y component of momentum
pz z component of momentum
E Hamiltonian (time-independent)
E Hamiltonian (time-dependent)
Ek Kinetic energy
Lz Z component of angular momentum
128
Minimum Energy of a Particle in a Box

• An important consequence of the uncertainty
  principle is that a particle confined to a finite
  space can not have zero kinetic energy.
• Lets consider a one-dimensional box of length
  L. If we know that the particle is in the box, ?x
  is not larger than L. This implies that ?p is at
  least h/L. Let us take the standard deviation as
  a measure of ?p

129
Minimum Energy of a Particle in a Box

• If the box is symmetric, p will be zero since
  the particle moves to the left as often as to the
  right. Then
• and the average kinetic energy is

130
Minimum Energy of a Particle in a Box

• The average kinetic energy of a particle in a
  box is
• Thus, we see that the uncertainty principle
  indicate that the minimum energy of a particle in
  a box cannot be zero. This minimum energy is
  called zero-point energy.

131
The Hydrogen Atom

• The energy of an electron of momentum p a
  distance r from a proton is
• If we take for the order of magnitude of the
  position uncertainty ?x r, we have
• (?p2) p2 ?2/r2
• The energy is then

132
The Hydrogen Atom

• There is a radius rm at which E is minimum.
  Setting dE/dr 0 yields rm and Em

rm came out to be exactly the radius of the first
Bohr orbit
The ground state energy
133
The Hydrogen Atom

• The potential energy of the electron-proton
  system varies inversely with separation distance
• As in the case of gravitational potential
  energy, the potential energy of the
  electron-proton system is chosen to be zero if
  the electron is an infinity distance from the
  proton. Then for all finite distances, the
  potential energy is negative.

134
The Hydrogen Atom

• Like the energies of a particle in a box and of
  a harmonic oscillator, the energy levels in the
  hydrogen atom are described by a quantum number
  n. The allowed energies of the hydrogen atom are
  given by
• En -13.6 eV/n2,
• n 1,2,3,

Energy-level diagram for the hydrogen atom. The
energy of the ground state is -13.6 eV. As n
approaches 8 the energy approaches 0.
135
Step Potential

• Consider a particle of energy E moving in region
  in which the potential energy is the step
  function
• U(x) 0, xlt0
• U(x) V0, xgt0
• What happened when
• a particle moving from
• left to right encounters
• the step?
• The classical answer is
• simple to the left of the
• step, the particle moves
• with a speed v v2E/m

136
Step Potential
At x 0, an impulsive force act on the particle.
If the initial energy E is less than V0, the
particle will be turned around and will then move
to the left at its original speed that is, the
particle will be reflected by the step. If E is
greater than V0, the particle will continue to
move to the right but with reduced speed given by
v v2(E U0)/m

137
Step Potential

• We can picture this classical problem as a ball
  rolling along a level surface and coming to a
  steep hill of height h given by mghV0.
• If the initial kinetic energy of the ball is
  less than mgh, the ball will roll part way up the
  hill and then back down and to the left along the
  lower surface at it original speed. If E is
  greater than mgh, the ball will roll up the hill
  and proceed to the right at a lesser speed.

138

• The quantum mechanical result is similar when E
  is less than V0. If EltV0 the wave function does
  not go to zero at x0 but rather decays
  exponentially. The wave penetrates slightly into
  the classically forbidden region xgt0, but it is
  eventually completely reflected.

139
Step Potential

• This problem is somewhat similar to that of
  total internal reflection in optics.
• For EgtV0, the quantum mechanical result differs
  from the classical result. At x0, the wavelength
  changes from
• ?1h/p1 h/v2mE
• to
• ?2h/p2 h/v2m(E-V0).
• When the wavelength changes suddenly, part of
• the wave is reflected and part of the wave is
  transmitted.

140
Reflection Coefficient

• Since a motion of an electron (or other
  particle) is governed by a wave equation, the
  electron sometimes will be transmitted and
  sometimes will be reflected.
• The probabilities of reflection and
  transmission can be calculated by solving the
  Schrödinger equation in each region of space and
  comparing the amplitudes of transmitted waves and
  reflected waves with that of the incident wave.

141
Reflection Coefficient

• This calculation and its result are similar to
  finding the fraction of light reflected from the
  air-glass interface. If R is the probability of
  reflection, called the reflection coefficient,
  this calculation gives
• where k1 is the wave number for the incident
  wave and k2 is the wave number for the
  transmitted wave.

142
Transmission Coefficient

• The result is the same as the result in optics
  for the reflection of light at normal incidence
  from the boundary between two media having
  different indexes of refraction n.
• The probability of transmission T, called the
  transmission coefficient, can be calculated from
  the reflection coefficient, since the probability
  of transmission plus the probability of
  reflection must equal 1
• T R 1
• In the quantum mechanics, a localized particle
  is represented by the wave packet, which has a
  maximum at the most probable position of the
  particle.

143

• Time development of a one dimensional wave
  packet representing a particle incident on a step
  potential for EgtV0. The position of a classical
  particle is indicated by the dot. Note that part
  of the packet is transmitted and part is
  reflected.

144

• Reflection coefficient R and transmission
  coefficient T for a potential step V0 high versus
  energy E (in units V0).

145

• A particle of energy E0 traveling in a region in
  which the potential energy is zero is incident on
  a potential barrier of height V00.2E0. Find the
  probability that the particle will be reflected.

146
Lets consider a rectangular potential barrier of
height V0 and with a given byU(x) 0, xlt0U(x)
V0, 0ltxltaU(x) 0, xgta
147
Barrier Potential

• We consider a particle of energy E , which is
  slightly less than V0, that is incident on the
  barrier from the left. Classically, the particle
  would always be reflected. However, a wave
  incident from the left does not decrease
  immediately to zero at the barrier, but it

will instead decay exponentially in the
classically forbidden region 0ltxlta. Upon reaching
the far wall of the barrier (xa), the wave
function must join smoothly to a sinusoidal wave
function to the right of barrier.
148
The potentials and the Schrödinger equations
for the three regions are as follows Region I
(xlt0) V 0, Region II (0ltxlta) V
V0, Region III (xgta) V 0,
149
Barrier Potential

• If we have a beam of particle incident from
  left, all with the same energy EltV0, the general
  solution of the wave equation are, following the
  example for a potential step,
• where k1 v2mE/h and a v2m(V0-E)/h
• This implies that there is some probability of
  the particle (which is represented by the wave
  function) being found on the far side of the
  barrier even though, classically, it should never
  pass through the barrier.

150

• We assume that we have incident particles
  coming from the left moving along the x
  direction. In this case the term Aeik1x in region
  I represents the incident particles. The term
  Be-ik1x represents the reflected particles moving
  in the x direction. In region III there are no
  particles initially moving along the -x
  direction. Thus G0, and the only term in region
  III is Feik1x. We summarize these wave functions

151
Barrier Potential

• For the case in which the quantity
• aa v2ma2(V0 E)/h2
• is much greater than 1, the transmission
  coefficient is proportional to e-2aa, with
• a v2m(V0 E)/h2
• The probability of penetration of the barrier
  thus decreases exponentially with the barrier
  thickness a and with the square root of the
  relative barrier height (V0-E). This phenomenon
  is called barrier penetration or tunneling. The
  relative probability of its occurrence in any
  given situation is given by the transmission
  coefficient.

152

• A wave packet representing a particle incident
  on two barriers of height just slightly greater
  than the energy of the particle. At each
  encounter, part of the packet is transmitted and
  part reflected, resulting in part of the packet
  being trapped between the barriers from same
  time.

153

• A 30-eV electron is incident on a square
  barrier of height 40 eV. What is the probability
  that the electron will tunnel through the barrier
  if its width is (a) 1.0 nm?
• (b) 0.1nm?

154

• The penetration of the barrier is not unique to
  quantum mechanics. When light is totally
  reflected from the glass-air interface, the light
  wave can penetrate the air barrier if a second
  peace of glass is brought within a few
  wavelengths of the first, even when the angle of
  incidence in the first prism is greater than the
  critical angle. This effect can be demonstrated
  with a laser beam and two 45 prisms.

155
a- Decay
The theory of barrier penetration was used by
George Gamov in 1928 to explain the enormous
variation of the half-lives for a decay of
radioactive nuclei.
Potential well shown on the diagram for an a
particle in a radioactive nucleus approximately
describes a strong attractive force when r is
less than the nuclear radius R. Outside the
nucleus the strong nuclear force is negligible,
and the potential is given by the Coulombs law,
U(r) k(2e)(Ze)/r, where Ze is the nuclear
charge and 2e is the charge of a particle.
156
a- Decay
An a-particle inside the nucleus oscillates back
and forth, being reflected at the barrier at R.
Because of its wave properties, when the
a-particle hits the barrier there is a small
chance that it will penetrate and appear outside
the well at r r0. The wave function is similar
to that for a square barrier potential.
157

• The probability that an a-particle will tunnel
  through the barrier is given by
• which is a very small number, i.e., the a
  particle is usually reflected. The number of
  times per second N that the a particle approaches
  the barrier is given by

where v equals the particles speed inside the
nucleus.
The decay rate, or the probability per second
that the nucleus will emit an a particle, which
is also the reciprocal of the mean life time
, is given by
158

• The decay rate for emission of a particles from
  radioactive nuclei of Po212. The solid curve is
  the prediction of equation
• The points are the experimental results.

159
Applications of Tunneling

• Nanotechnology refers to the design and
  application of devices having dimensions ranging
  from 1 to 100 nm
• Nanotechnology uses the idea of trapping
  particles in potential wells
• One area of nanotechnology of interest to
  researchers is the quantum dot
• A quantum dot is a small region that is grown in
  a silicon crystal that acts as a potential well
• Nuclear fusion
• Protons can tunnel through the barrier caused by
  their mutual electrostatic repulsion

160
Resonant Tunneling Device

• Electrons travel in the gallium arsenide
  semiconductor
• They strike the barrier of the quantum dot from
  the left
• The electrons can tunnel through the barrier and
  produce a current in the device

161
Scanning Tunneling Microscope

• An electrically conducting probe with a very
  sharp edge is brought near the surface to be
  studied
• The empty space between the tip and the surface
  represents the barrier
• The tip and the surface are two walls of the
  potential well

162
Scanning Tunneling Microscope

• The STM allows highly detailed images of surfaces
  with resolutions comparable to the size of a
  single atom
• At right is the surface of graphite viewed with
  the STM

163
Scanning Tunneling Microscope

• The STM is very sensitive to the distance from
  the tip to the surface
• This is the thickness of the barrier
• STM has one very serious limitation
• Its operation is dependent on the electrical
  conductivity of the sample and the tip
• Most materials are not electrically conductive at
  their surfaces
• The atomic force microscope (AFM) overcomes this
  limitation by tracking the sample surface
  maintaining a constant interatomic force between
  the atoms on the scanner tip and the samples
  surface atoms.

164
SUMMARY

• 1. Time-independent Schrödinger equation
• 2.In the simple harmonic oscillator
• the ground wave function is given
• where A0 is the normalization constant and
  am?0/2h.
• 3. In a finite square well of height V0, there
  are only a finite number of allowed energies.

165
SUMMARY

• 4.Reflection and barrier penetration
• When the potentials changes abruptly over a
  small distance, a particle may be reflected even
  though EgtU(x). A particle may penetrate a region
  in which EltU(x). Reflection and penetration of
  electron waves are similar for those for other
  kinds of waves.