p roperties of w aves refraction of light and sound waves
TRANSCRIPT
PROPERTIES OF WAVESRefraction of Light and Sound Waves
REFRACTION
When light bends in going obliquely from one medium to another, we call this process refraction.
REFRACTION
Refraction occurs to minimize the time taken by light to travel from A to B.
Just as if you wanted to save someone from drowning, the quickest path would not be a straight line – it would be the dashed path shown.
REFRACTION
Light follows a less inclined path in the glass.• Light travels slower in glass than in air, so it minimizes
the time it spends in the glass.
REFRACTION
Light rays pass from air into water and water into air.• Pathways are reversible for both reflection and
refraction.
INDEX OF REFRACTION
Index of refraction, n, of a material indicates how much the speed of light
differs from its speed in a vacuum. indicates the extent of bending of rays. ratio of speed of light in a vacuum to
the speed in a material.
INDEX OF REFRACTION
The generally accepted speed of light in a vacuum is 3.00 x 108m/s; however, the speed of light varies according to the material that is travelling through. The speed of light in liquids and solids is significantly less than in a vacuum.
The ratio of the speed of light in a vacuum (c), to the speed of light in a given material (v), is called the absolute index of refraction (n) of the material.
n = c . also known as c = nv also known as v = c . v c = vn
n
Just by looking at this formula, we can predict: The unit(s) of the index of refraction: there
are none! It’s a ratio The greater the index of refraction for a
given material, the slower the speed of light in that substance.
The minimum possible index of refraction of a substance would be 1. An index of refraction less than 1 would mean that…
Example 1:The speed of light in water is m/s. What is the index of refraction for water?
Example 2:The index of refraction for diamond is 2.42. What is the speed of light in diamond?
REFRACTION OF LIGHT
The change in the speed of light as it passes from one medium into another causes it to bend.
Refraction is the bending of light that takes place at a boundary between two materials having difference indices of refraction.
REFRACTION OF LIGHT
CAREFUL….with reflection, the angle of incidence equaled the angle of reflection. With refraction the same is not true.
How can we determine the angle of refraction given the angle of incidence? Let’s do the refraction lab to figure this out!
REFRACTED LIGHT THAT BENDS TOWARD THE NORMAL IS LIGHT THAT HAS
A. slowed down.B. sped up. C. nearly been absorbed.D. diffracted.
RefractionCHECK YOUR NEIGHBOR
REFRACTED LIGHT THAT BENDS TOWARD THE NORMAL IS LIGHT THAT HAS
A. slowed down.B. sped up. C. nearly been absorbed.D. diffracted.
RefractionCHECK YOUR ANSWER
REFRACTED LIGHT THAT BENDS AWAY FROM THE NORMAL IS LIGHT THAT HAS
A. slowed down.B. sped up. C. nearly been absorbed.D. diffracted.
RefractionCHECK YOUR NEIGHBOR
REFRACTED LIGHT THAT BENDS AWAY FROM THE NORMAL IS LIGHT THAT HAS
A. slowed down.B. sped up. C. nearly been absorbed.D. diffracted.
Explanation:This question is a consistency check with the question that asks about light bending toward the normal when slowing.
RefractionCHECK YOUR ANSWER
REFRACTION
Illusions caused by refraction
Objects submerged in water appear closer to the surface.
REFRACTION
Illusions caused by refraction (continued)
Objects such as the Sun seen through air are displaced because of atmospheric refraction.
REFRACTION
Illusions caused by refraction (continued)
Atmospheric refraction is the cause of mirages.
WHEN LIGHT TRAVELS FROM ONE MEDIUM TO ANOTHER AND CHANGES SPEED IN DOING SO, WE CALL THE PROCESS
A. reflection.B. interference. C. dispersion.D. refraction.
RefractionCHECK YOUR NEIGHBOR
WHEN LIGHT TRAVELS FROM ONE MEDIUM TO ANOTHER AND CHANGES SPEED IN DOING SO, WE CALL THE PROCESS
A. reflection.B. interference. C. dispersion.D. refraction.
RefractionCHECK YOUR ANSWER
DISPERSION Newton performed experiments that illustrated
the dispersion of sunlight into a spectrum and subsequent recombination into white light.
Components of whit light are dispersed in a prism (and in a diffraction grating.)
A dispersive medium is one in which different wavelengths of light have slightly different indices of refraction. For example, crown glass is a dispersive medium since the index of refraction for violet light in crown glass is higher than for red light. This is responsible for chromatic aberration.
RAINBOWS
Rainbows are a result of dispersion by many drops.
Dispersion of light by a single drop
RAINBOWS Sunlight incident on two sample raindrops, as
shown, emerges from them as dispersed light. The observer sees the red light from the upper
drop and the violet light from the lower drop. Millions of drops produce the whole spectrum of
visible light.
SNELL’S LAW
Dutch Mathematician Willebrod Snell (1591 – 1626) determined the exact relationship between the angle of incidence and the angle of refraction.
LAW OF REFRACTION
Summarized: The ratio of the sine of the angle of incidence
to the sine of the angle of refraction is a constant (also known as Snell’s Law).
The incident ray and the refracted ray are on opposite sides of the normal at the point of incidence, and all three are coplanar.
EXAMPLE 1:
Light passes from air into water at an angle of incidence of 50 degrees. What is the angle of refraction?
EXAMPLE 2:
If the angle of refraction of light in crown glass is 30 degrees, what is the angle of incidence? Index of Refraction for Crown glass = 1.52
GENERAL FORM OF SNELL’S LAW
PROBLEM! This version of Snell’s Law is only valid of the first medium is air. For any two media we must use the General Form of Snell’s Law:
n1sinθ1 = n2sinθ2
* This equation works for all cases of refraction!
EXAMPLE 3:
Light passes from water to into quartz at an angle of incidence of 30 degrees. What is the angle of refraction? Include a diagram.
EXAMPLE 4:
Light passing from flint glass into ethanol refracts at an angle of degrees. What is the angle of incidence? Include a diagram.
ASSIGNEMENT:
Snell’s Law Assignment (p.18) Refraction Problems (p.19)
CRITICAL ANGLE AND TOTAL INTERNAL REFLECTION
At a boundary, an incident ray can undergo partial reflection, or, in certain situations total internal reflection.
The critical angle is the angle of incidence for which the angle of refraction is 90. At this angle, the refracted ray glances parallel to the boundary
At any angle of incidence greater than the critical angle, total internal reflection occurs. This means that no light passes through the boundary.
Total internal reflection is only possible if light is travelling from a more refractive medium to a less refractive medium. (i.e. n2 < n1 )
Without total internal reflection, there would be no such thing as fibre optics! YIKES! A world without fibre optics technology would be a world without:
The InternetCable TVmedical cameras
EXAMPLE:
Determine the critical angle for a crown glass and water boundary.
LENSES
Types of Lenses:Lenses are of two basic types – Converging and Diverging
Converging – thicker in the middle than the ends
Diverging – thinner in the middle than the ends Note: Incident light rays are refracted twice by a
lens; once at each boundary. To simplify matters on ray diagrams, incident rays can be shown to refract at the construction line passing through the optical centre of the lens. For a thin lens this leads to a reasonably close approximation because the lateral displacement is quite small.
ABERRATIONS
Lens defects are called aberrations. They hinder the quality of the image formed. They can be corrected by using aspheric lenses or by using thin lens combinations that cancel out aberrations.
RAY DIAGRAMS FOR LENSES How lens diagrams are different from curved
mirror diagrams: Instead of a Vertex (V), a lens has an optical centre
(O) which is located at its geometric centre A lens has two foci, equidistant on either side of
the lens, since light behaves the same way when travelling in either direction (Principle of Reversibity). The two foci, F and F' are called the primary principal focus and the secondary principal focus, respectively. F, sometimes also referred to as the primary focal point, is shown on the right side of a converging lens, and on the left side of a diverging lens, while F', the secondary focal point is shown on the opposite side of each respective lens.
RULES FOR DRAWING RAY DIAGRAMS FOR CONVERGING AND DIVERGING LENSES
(Parenthetical remarks refer specifically to diverging lenses)
An incident ray that is parallel to the principal axis is refracted such that it passes through (or appears to have originated from) the principal focus (F).
An incident ray passing through (or heading toward) the secondary principal focus (F') is refracted such that it travels parallel to the principal axis.
An incident ray passing through the optical centre of the lens continues to travel in a straight line.
EXAMPLES FOR CONVERGING & DIVERGING LENS:
THIN LENS EQUATION
Lens problems are very similar to those done with curved mirrors.
Thin Lens Equation
= + Magnification Equation
M = = -
SIGN CONVENTION:
di is positive for real images and negative for virtual images
f is positive for converging lenses, and negative for diverging lenses.
EXAMPLE 1:
An object is 32.0 cm to the left of a converging lens with a focal length of 8.0 cm. Where is the image located?
EXAMPLE 2:
An object 3.0 cm tall is placed 2.0 cm to the left of a diverging lens with a focal length of 3.5 cm. Where is the image located, and what is its size?