Chapter 10: Wave Optics

Chapter 10: Wave Optics

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Resolving power depends

Wavelength

Aperture

Both

None

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Central fringe white light

Red

Blue

White

Dark

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Fringe width independent

Wavelength

Distance

Slit separation

Intensity

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Diffraction vs interference

Same

Different

Slit number

No relation

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Interference requires

Coherent

High intensity

Same medium

Same amplitude

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Cannot polarize

Light

EM waves

Sound

X-rays

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Sunglasses reduce

Increase light

Glare

Color

Intensity

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Polarization by reflection

Any angle

Brewster

Critical

90°

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Polaroids used for

Reflection

Refraction

Polarization

Diffraction

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At Brewster angle

Perpendicular

Parallel

Same

Zero

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Brewster law

sin i/sin r

tan i

cos i

sec i

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Plane polarized

One dir

Two dir

Three dir

Random

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Unpolarized light

One plane

Random

No vibration

Fixed phase

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Polarized waves

Longitudinal

Transverse

Sound

Mechanical

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Polarization proves

Particle

Transverse wave

Dual

Longitudinal

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Max intensity

Same

Decreasing

Increasing

Zero

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Angular width ∝

Wavelength

1/slit width

Distance

Intensity

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Diffraction proves

Particle

Wave

Magnetic

Electric

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Narrow slit →

Narrow

Wide

Same

Absent

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Depends on

Slit width

Intensity

Phase

Amplitude

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First minima

a sinθ=λ

a sinθ=2λ

a sinθ=λ/2

a=λ

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Width central max

Equal

Twice

Half

Zero

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Central max

Dark

Bright

Colored

Narrow

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Significant diffraction when

Large slit

~ wavelength

Very small

Infinite

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Diffraction due to

Reflection

Bending

Refraction

Dispersion

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Interference proves

Particle

Wave

Dual

Relativity

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Phase diff depends on

Path diff

Intensity

Speed

Medium

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Pattern disappears if

Incoherent

Distance ↑

Narrow slits

Bright light

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Screen distance ↑

Increase

Decrease

Same

Zero

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Monochromatic light

White

Colored

Alt bright-dark

Only bright

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Phase diff bright

π

2πn

π/2

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Slit distance decreases →

Increases

Decreases

Same

Zero

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Central fringe

Dark

Bright

Colored

Absent

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Wavelength increases →

Decreases

Increases

Same

Zero

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Coherent sources have

Same amplitude

Same phase diff

Same intensity

Same speed

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Fringe width formula

λD/d

dD/λ

λ/d

D/λ

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Fringe width depends on

Intensity

Wavelength

Colour

Amplitude

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Destructive condition

nλ

(2n+1)λ/2

λ

2λ

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Constructive condition

(2n+1)λ/2

nλ

λ/4

None

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Interference due to

Reflection

Refraction

Superposition

Diffraction

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Refraction due to change in

Frequency

Speed

Amplitude

Phase

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Wavefront velocity

Group

Phase

Angular

Relative

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Speed depends on

Frequency

Amplitude

Medium

Phase

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Rays are

Tangential

Perpendicular

Parallel

Random

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Wavefront perpendicular to rays

Spherical

Plane

Cylindrical

Secondary

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Reflection laws derived using

Newton laws

Snell law

Huygens principle

Maxwell eqns

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Plane wavefront obtained from

Point source

Distant source

Line source

Small slit

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Shape of wavefront from point source

Plane

Cylindrical

Spherical

Elliptical

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Huygens principle states every point acts as

Energy source

Secondary wavelet

Reflection point

Diffraction slit

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A wavefront is defined as

Locus of same phase

Path of light

Direction of wave

Amplitude curve

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