PHYS 252Part 1: Light

• what is light?

Light

what is light: moving energy• wave or particle?

Light

what is light: moving energy• wave or particle?

• how do we decide?

Light

what is it? moving energy• wave or particle?

• how do we decide?

• if a wave, what is waving?

(waving even in a vacuum?)

Light

what is it? moving energy• wave or particle?

• how do we decide?

if a wave, what is waving?

(waving even in a vacuum?)

Electric & Magnetic Fields

Properties of Light

• speed of light

• colors

• reflection

• refraction (bending)

• shadows

• energy theory

• absorption of light

• emission of light

Property 1: Speed of Light

• particle (photon) ?

Property 1: Speed of Light

particle (photon): no prediction

• wave (E&M) ?

Property 1: Speed of Light

particle (photon): no prediction

wave (E&M): Maxwell’s Eqs.

wave equation from Maxwell’s Eqs:

E / x = t2 2 2 2 E /

Property 1: Speed of Lightparticle (photon): no prediction

wave (E&M): Maxwell’s Eqs.

wave equation from Maxwell’s Eqs: is similar to the wave equation for a string:

where y = y(x+/- vt) and v = [T/μ]1/2

v x = t2 2 2 2 2 y y/ /

F T x = t ory2 2 2 2 ma y y / /

Property 1: Speed of Light

particle (photon): no prediction

wave (E&M): Maxwell’s Eqs.

wave equation from Maxwell’s Eqs predicts:

v = 1 / ( )o

E / x = t2 2 2 2 E /

E = E(x +/- vt) where

Property 1: Speed of Light

particle (photon): no prediction

wave (E&M): Maxwell’s Eqs.

in vacuum: v = [1/(μoεo)]1/2 where

μo = 4π x 10-6 T*m/A and

εo = 1 / [4πk] = 1 / [4π x (9 x 109 Nt-m2/C2)] sov = c = [1 / {(4π x 10-7)/ (4π x 9 x 109}]1/2 m/s = [9 x 1016]1/2 m/s = 3 x 108 m/s

= 670 million miles/hour

Property 1: Speed of Light

particle (photon): no prediction

wave (E&M): Maxwell’s Eqs.

in material, v = [1/(με)]1/2

= K , K > 1 ; so

v (in material) < c (in vacuum)

Property 1: Speed of Light

particle (photon): no prediction

wave (E&M): in vacuum, v = c; in material, v < c

we’ll come back to this when we look at property 4 (refraction) and in Part 4 of the course when we look at Special Relativity.

Property 2: Color

• experiment ?

• particle (photon) ?

• wave (E&M) ?

Property 2: Color

Experiment:– invisible as well as visible– total spectrum order:

• radio• microwave• IR• visible• UV• x-ray and gamma ray

Property 2: Color

Experiment:– visible order:

• red

• orange

• yellow

• green

• blue

• violet

Property 2: Color

particle (photon):

amount of energy per photon

determines “color”

Property 2: Color

particle (photon): amount of energy

• among different types:

x-ray - most energy; radio - least

• in visible portion:

violet - most energy; red - least

Property 2: Color

particle (photon): amount of energy

• wave (E&M) ?

Property 2: Color

particle (photon): amount of energy

wave (E&M): frequencyamong different types of “light”: low frequency is radio (AM is 500-1500 KHz) high frequency is x-ray & gamma rayin visible spectrum: red is lowest frequency (just above IR)

violet is highest frequency (just below UV)

Property 3: Reflection

• particle (photon) ?

• wave (E&M) ?

Property 3: Reflection

particle (photon): bounces “nicely”

wave (E&M): bounces “nicely”

bounces nicely means:

angle incident = angle reflected

Reflection

Does a white paper reflect the light, or does a white paper emit from itself the light? - Obviously, the white paper reflects the light.

Does a mirror reflect light? Of course.

What is the difference between white paper and a mirror?

ReflectionA white paper is rough on a microscopic level, and

so a beam of light is reflected in all directions:

A mirror is smooth on a microscopic level, and so a beam of light is all reflected in just one direction.

rough paper smooth mirror

Red is incoming, blue is outgoing

Property 4: Refraction

• experiment ?

• particle (photon)?

• wave (E&M) ?

Property 4: Refraction

experiment: objects in water seem closer than they really are when viewed from air

air

water

real object

apparentlocation

eye

Property 4: Refraction

• particle (photon) ?

water

air

surface

incident ray

refracted ray

Property 4: Refraction

particle (photon):

water

air

surface

incident ray

refracted ray

vxa

vya

vxw

vyw

vxa = vxw

vya < vyw

therefore

va < vw

Refraction: particle theory

Since v1x = v2x, using the angles between the normal (the vertical) and the light rays, we have: vx1 = vx2, or v1 sin(1) = v2 sin(2) , and we have the Pythagorean Theorem: [v2 sin(2)]2 + [v2 cos(2)]2 = v2

2 , or [v2 sin(2)]2 = v2

2 - [v2 cos(2)]2 , so if we substitute the first equation in the second, we get [v1 sin(1)]2 = v2

2 - [v2 cos(2)]2 or[v1 sin(1)]2 = v2

2 [1 - cos(2)]2 = [v2 sin()]2 or

v1 sin(1) = v2 sin() (faster speed means smaller angle)

Property 4: Refraction

• wave (E&M) ?

surface

air

water

incident wave

refracted wavenormal line

Property 4: Refraction

wave (E&M):

surface

air

water

incident wave

refracted wave

crest of wave

crest of preceding wave

x

a

w

normal line

crest of following wave

Property 4: Refraction

wave (E&M): + = 90o

+ = 90o

surface

air

water

incident wave

refracted wave

crest of wave

crest of preceding wave

x

a

w

normal line

sin() = a/x

sin() = w/x

Property 4: Refraction

wave (E&M):

sin(a) = a/x and sin(w) = w/x

eliminate x: a/sin(a) = w/sin(w) and use: f = v (or = v/f) to get

f sin(a) / va = f sin(w) / vw

NOTE: since a > w, need va > vw

which is opposite to the prediction of the particle theory but agrees with wave prediction of Property 1 on speed!

Property 4: Refraction

wave (E&M):

nicer form: f sin(a) / va = f sin(w) / vw

Multiply thru by c/f to get

(c/va) sin(a) = (c/vw) sin(w)

and use definition of index of refraction:

n = c/v to get

na sin(a) = nw sin(w) Snell’s Law

Property 4: Refraction

particle (photon) theory: vw > va

wave (E&M) theory: vw < va

• experiment ?

Property 4: Refraction

particle (photon) theory: vw > va

wave (E&M) theory: vw < va

experiment: vw < va

wave theory works!

particle theory fails!

Properties 1, 2 & 4

Speed, Color and RefractionSpeed of light changes in different materials

Speed is related to frequency and wavelength: v = f

• If speed changes, does wavelength change, frequency change, or BOTH?

Properties 1, 2 & 4

Speed, Color and RefractionSpeed of light changes in different materials

Speed is related to frequency and wavelength: v = f• What changes with speed:

– Frequency remains constant regardless of speed– Wavelength changes with speed

Property 4: Refraction

Snell’s Law:

na sin(a) = nw sin(w)

• Note that angles are measured from the normal, not the surface.

• Note that the index of refraction is bigger for slower speeds.

Property 4: Refraction

Snell’s Law: n1 sin(1) = n2 sin(2)

• NOTE: If n1 > n2, THEN 1 < 2 .

• NOTE: All 1 values between 0 & 90 degrees work fine.

• NOTE: Not all values of 2 work!

Example: If n1 = 1.33, n2 = 1, and 1 = 75o, then

2 = inv sin [n1 sin(1) / n2] = inv sin [1.28] = ERROR

Property 4: Refraction

Snell’s Law: n1 sin(1) = n2 sin(2)

• If n1 sin(1) / n2 > 1 THEN there is NO value of 2 that can satisfy Snell’s law (unless you count imaginary angles!).

The math is trying to tell us that there is NO transmitted ray. This is called

TOTAL INTERNAL REFLECTION.

Property 4: Refraction

• The computer homework program (entitled Snell’s Law, vol. 5, #1) will give you practice is using Snell’s Law.

• We will now halt our look at light’s different properties, and look at some important applications of Refraction for the rest of Part 1. We will continue looking at other properties in Part 2 of the course.