2. Properties of Light
• Effects of Materials on Light
• Reflection
• Refraction
• Dispersion
• Total Internal Reflection
• Interference
• Diffraction
• Scattering of Light
• Polarization
3. Effects of Materials on Light
Materials can be classified based on how it
responds to light incident on them:
1. Opaque materials – absorb light; do
not let light to pass through
2. Transparent materials – allow light to
easily pass through them
3. Translucent materials – allow light to
pass through but distorts the light
during the passage
4. Reflection
Light follows the Law of Reflection: “The
angle of incidence is equal to the angle of
reflection.”
Light can bounce off materials in two ways:
1. Diffuse reflection – reflected rays go in
different directions; happens in rough-
textured or uneven surfaces
2. Regular/Specular reflection – reflected
rays go in one directions; happens in
smooth and shiny surfaces; image can be
seen
5. Refraction
Light bends/refracts when it changes speed.
This usually happens when the light travels
from one medium to the next.
Simple rule of thumb in refraction:
• If light slows down, it will refract towards
the normal line.
• If light speeds up, it will refract away from
the normal line.
6. Refraction
Light travels faster in air, slow in water and
slower still in glass.
The slower light is in a medium, the more it
refracts/bends in it.
The measure of how much light refracts in a
medium is called index of refraction.
Medium
Index of
Refraction (n)
air 1.000293
water 1.3330
glass 1.490
diamond 2.419
7. Refraction
Light follows the Law of Reflection: “The
angle of incidence is equal to the angle of
reflection.”
Light can bounce off materials in two ways:
1. Diffuse reflection – reflected rays go in
different directions; happens in rough-
textured or uneven surfaces
2. Regular/Specular reflection – reflected
rays go in one directions; happens in
smooth and shiny surfaces; image can be
seen
8. Refraction
Light follows the Law of Reflection: “The
angle of incidence is equal to the angle of
reflection.”
Light can bounce off materials in two ways:
1. Diffuse reflection – reflected rays go in
different directions; happens in rough-
textured or uneven surfaces
2. Regular/Specular reflection – reflected
rays go in one directions; happens in
smooth and shiny surfaces; image can be
seen
9. Dispersion
The process in which
light is separated into
its colors due to the
differences in degrees
of refraction.
How are
rainbow
s
formed?
10. Total Internal Reflection
When light is reflected
completely at the
boundary between
two mediums
How do
fiber
optics
work?
Why do
diamonds
11. Diffraction
Light spreads out after passing through/by
an opening /edge.
The opening must be very narrow for
diffraction of light to occur.
“Every cloud
has a silver
lining.”
14. Reflection
• Reflection - Light bounces off the surfaces
like mirrors such that the angle of
incidence is equal to the angle of
reflection.
• Refraction - Refraction is defined as the
bending of light as it passes through
materials of different optical density
• Interference - When two light waves meet
or coincide, it can create either
constructive or destructive interference
based on how the crests & troughs of the
waves meet.
15. Wave Properties (Light)
• Diffraction - This is defined as the
bending of light waves around
obstacles in its path.
Example, when a light wave passes
through a barrier with a small
opening, it acts as a single point
source from where light emerges
and spreads in all direction.
16. • Light has a dual nature.
• Depending on the phenomenon or behavior in
question, light can be treated either as a wave
or as a particle.
• To examine this wave-particle duality, we will
examine two experimental proofs.
So, is light a wave or a particle?
17. • Conducted by Thomas Young in the early 1800’s
• Provided an experimental basis for considering light as
a wave.
Light is a WAVE: Young’s Double-Slit Experiment
18. • The individual slits acted as individual sources
which light passes through and spreads.
(Isn’t this like water waves?)
• Light exhibits interference which is a wave
property.
Key Points of Young’s Experiment
19. • Explained by Einstein
during the early 1900’s
• Provided an
experimental basis for
considering light as a
particle.
• Einstein earned a
Nobel Prize for his
explanation.
Light is a PARTICLE: The Photoelectric Effect
20. • Higher energy light knocks off electrons at higher
energy.
• The number of ejected electrons is directly related to
the intensity (brightness) of light. This means
brighter lights emit more photons.
• Light is a particle since it is capable of ‘knocking off’
electrons. Further, unlike waves, increasing the
brightness does not increase the energy of the
knocked off electrons.
Key Points of Photoelectric effect