Photoelectric Effect Lecture Notes PDF

Summary

These lecture notes explain the photoelectric effect, starting with the concept of how classical physics breaks down on small scales and how quantum mechanics is appropriate for explaining the behavior of subatomic particles. The notes detail experimental evidence that light exhibits particle-like properties and discuss the relationship between the energy of light and the kinetic energy of emitted electrons.

Full Transcript

10/3/24

Quantum Mechanics
Classical (Newtonian) physics/mechanics begins to
deteriorate on small scales.

Quantum mechanics/physics is appropriate in
the microscopic world.
Quantum physics needs complex math to explain the
behaviors and properties of small particles because
the world of these subatomic particles is a very
bizarre one, filled with quantum probabilities.

1

The Particle-Like Properties of
Electromagnetic Radiation
We will study early experiments

that provided evidence that light, which we have
treated as a wave phenomenon,

has properties that we normally associate with
particles.

2

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Photoelectric Effect
More Readings
Serway
3.4
More Readings
Thornton
3.6
3

The Photoelectric Effect
The Photoelectric Effect:
When a metal surface is illuminated with light,
electrons could be emitted from the surface.
e
light
In 1887 Heinrich Hertz e
discovered this
phenomenon during
his research.

4

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— Light falls on a metal
surface (the emitter) in an
evacuated tube.
Light
— It can release electrons CATHODE
Emitter Collector
ANODE
which travel to the
collector. Electrons
I
A
Evacuated quartz tube

V

The Photoelectric Effect.

5

The released electrons have different kinetic energies (K)
according to their binding energies (ΔE) to the metal.
The work function Φ is the minimum energy needed to remove an
electron from a certain material.
e.g. Φ(Na) = 2.28 eV and Φ(Al) = 4.08 eV K = Elight - Δ E
K1 K2
Kmax= 3 eV Kmax = Elight– Φ
K3 K= 2 eV
K= 3 eV
K= 1eV
Kmax= 3 eV

K= 3 eV
4 eV 4 eV 4 eV 4 eV 4 eV 4 eV

Φ = ΔE|min
ΔE=2 eV ΔE=1 eV ΔE=3 eV ΔE=1 eV Φ=1 eV
work
function
Φ metal Φ

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Kmax is:
The maximum kinetic energy of electrons.

The energy of the most energetic electrons.

The energy of the electrons that
had the minimum binding
energy (the work function) to
the metal.

1
K max = m v 2max
2

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— The stopping potential Vs :
The potential that is just enough to repel the most
energetic electrons (that have Kmax ). The potential
at which the ammeter current drops to zero.

At this point:
-V s
Kmax = e Vs
e is the magnitude of the electron charge
Kmax is the maximum kinetic energy of electrons
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The classical point of view:
— The surface of the metal is illuminated by an EMW
of intensity I. An electron absorbs energy from the
wave until the binding energy of the electron to the
metal is exceeded, at which point the electron is
released.
e e e
Remember

As I increases Kmax increases and
electrons need shorter time to be emitted.

The experimental results:
(1) Kmax (determined from Vs ) is
totally independent of the
intensity I of the light source.

This result
disagrees with -V s

the classical
wave theory
which predicts
that Kmax should Vs remains the same
i.e. Kmax remains the same
depend on I.

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(2)The photoelectric
effect does not occur
if the frequency of
the light source, f , is
f o3
below a certain
value called the f
f o2 f o1
critical frequency or
the threshold
frequency fc or fo.

If f > fc even if I is very weak electron emission
If f < fc even if I is very strong No electron emission
This result disagrees with the classical wave theory.

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(3)The first photoelectron are emitted within 10 -9 s after
the light source is turned ON , whatever the value of I.

This result disagrees with the classical wave theory.
It predicts a measurable time delay.

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Einstein's Hypothesis 1905
— Einstein proposed that the energy of a light wave is
concentrated in localized particles called "light quanta"
or photons.
— The energy of a photon is:
E=h f
h is Planck’s constant = 6.623 x 10-34 J.s
f is the frequency of EMW hc
E=
E λ
However, p=
c Then,
h
E2 = Eo2 + p2c2. p=
λ
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Intensity of light = N h f

where N is the number of photons per second
per unit area

Increasing the intensity of light means increasing the
number of photons. The energy of each photon (hf)
depends on the frequency of the wave not on the
intensity.

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Einstein Explanation for Photoelectric Effect:
— A photoelectron is released as a result
of absorbing a single photon.
— The entire energy of the photon (hf ) is
delivered instantaneously to a single
electron.
— If hf > Φ, the photoelectron will E= hf

be released. f > Φ / h
— If hf Φ, the excess energy appears as the
kinetic energy of the most energetic electron:
h f = Kmax + Φ

Kmax = h f – Φ

No relation with intensity of light
— A photon of energy = Φ corresponds to light of
frequency equal to the cutoff frequency f c.
h fc = Φ
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Doubling I means twice as many photons strike the
surface and twice as many photoelectrons are
released. In both cases Kmax is the same

Intensity of light= N h f

That is Kmax depends only on the frequency of the light.

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Explanation of the experimental results:
(1)Kmax (determined from Vs ) is
totally independent of the
intensity I of the light source.
Kmax = hf - Φ
No relation with intensity of
light.
Doubling I means twice as many
photons strike the surface -V s
and twice as many
photoelectrons are released.
In both cases Kmax and hence
Vs are the same
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(2)The photoelectric effect
does not occur if the
frequency of the light
source, f , is below a f o3

certain value called the f o2 f o1
f

critical frequency or the
threshold frequency fc or
fo. It depends on the Photoelectric Effect

material.
Kmax = h f - Φ If h f