Presentation is loading. Please wait.

Presentation is loading. Please wait.

An incident ray from air strikes dolomite (n = 2.0) at an angle of 30 o from normal. Calculate:  refl &  refr.

Published byPaul Lindsey Modified over 8 years ago

Similar presentations

Presentation on theme: "An incident ray from air strikes dolomite (n = 2.0) at an angle of 30 o from normal. Calculate:  refl &  refr."— Presentation transcript:

1 An incident ray from air strikes dolomite (n = 2.0) at an angle of 30 o from normal. Calculate:  refl &  refr

2 Chapter 19 Diffraction & Interference

3 List & describe 3 properties of waves

4 Diffraction The bending of light rays when passing a barrier

5 Diffraction Named by Francesco Grimaldi by seeing blurred edges of shadows

6 Isaac Newton Predicted that light moved in the form of particles to explain diffraction

7 Christiaan Huygens Predicted that light moved in the form of waves to explain diffraction

8 Thomas Young Proved that light moved in the form of waves by passing light thru a double slit. P 445

9 Thomas Young The interference pattern caused by diffraction produced dark & light lines

10 Monochromatic Light Light having only one wavelength

11 Coherent Waves Waves all in the same phase

12 Diffraction Interference Light waves d n n L  x x L d =

13 Diffraction Interference x L d = xd L = Double slit

14 Calculate wavelength reinforced when waves passing through 2 slits 25  m apart cast bright lines 4.0 cm apart on a screen 2.0 m away

15 Calculate wavelength reinforced when waves passing through 2 slits 25  m apart cast bright lines that make a 37 o angle from the principle axis

16 Diffraction Interference d = distance between slits w = slit width xd xw L L = =

17 Diffraction Interference Light waves d n n L  x  d sin 

18 Wave Properties Propagation Reflection Refraction Diffraction Interference

19 Propagation Within a uniformed medium, the generation of waves that move in straight lines called rays

20 Reflection The bouncing of waves off surfaces or medium boundaries

21 Refraction The bending of waves when passing from one medium to another

22 Diffraction The bending of waves when passing around barriers

23 Interference The superimposing two or more waves passing through the same medium simultaneously

24 Photoelectric Effect The emission of electrons (e - )from a substance when irradiated

25 1 st Law of Ph Eff The rate of e - emission is proportional to the intensity of the incident light

26 2 nd Law of Ph Eff The KE of e - emission is independent of the intensity of the incident light

27 Photoelectric Effect This led to the discovery that e - in atoms exist in distinct energy levels

28 Spectroscopy The study of a substance under continuous excitation energy

29 Energy of a Wave E wave = hf

30 Energy of Matter E matter = mc 2

31 Duality of Nature Proposed by Louis de Broglie

32 Duality of Nature All energy transfer exhibits properties of both waves & particles

33 Duality Formula = h mv

34 Calculate the wavelength 2.21 kg of a ball thrown at 20.0 m/s

35 Calculate the mass of blue light at 442 nm

36 Calculate the wavelength of a 442 Mg truck moving at 36 km/hr

37 Calculate the wavelength of a 4.42 x 10 6 Mg train moving at 72 km/hr

38 The of near IR red light is 663 nm. Calculate: E & m of the light

39 The of near UV light is 221 nm. Calculate: E & m of the light

40 Calculate wavelength reinforced when waves passing through 2 slits 25  m apart cast bright lines that make a 53 o angle from the principle axis

41 Calculate wavelength reinforced when waves passing through a slit 75  m slit cast bright lines that make a 53 o angle from the principle axis

42 Calculate wavelength reinforced when waves passing through 2 slits 75  m apart cast bright lines 5.0 cm apart on a screen 2.5 m away

43 Calculate wavelength reinforced when waves passing through a 15  m slit cast bright lines 3.0 cm apart on a screen 2.5 m away

44 A wavelength 180 nm is reinforced when waves passing through a 15  m slit cast bright lines 3.0 cm apart. What is the screen distance?

45 A wavelength 18 nm is reinforced when waves passing through a 1.5  m slit cast bright lines 3.0 cm apart. What is the screen distance?

46 Review

47 Calculate wavelength reinforced when waves passing through a 25  m slit cast bright lines 5.0 cm apart on a screen 2.5 m away

48 Calculate the mass & energy of UV light at 221 nm.

49 Calculate Kinetic energy & wavelength of a 442 g ball going 30.0 m/s

50 Calculate wavelength reinforced when waves passing through a slit 4.5  m slit cast bright lines that make a 37 o angle from the principle axis

Download ppt "An incident ray from air strikes dolomite (n = 2.0) at an angle of 30 o from normal. Calculate:  refl &  refr."

Similar presentations

Thin Films, Diffraction, and Double slit interference

Thin Films, Diffraction, and Double slit interference
Light Chapter 16-19.

Light Chapter
1308 E&M Diffraction – light as a wave Examples of wave diffraction: Water waves diffract through a small opening in the dam. Sound waves diffract through.

1308 E&M Diffraction – light as a wave Examples of wave diffraction: Water waves diffract through a small opening in the dam. Sound waves diffract through.
Wave Behavior Another McGourty-Rideout Production.

Wave Behavior Another McGourty-Rideout Production.
Chapter 24 Wave Nature of Light: © 2006, B.J. Lieb

Chapter 24 Wave Nature of Light: © 2006, B.J. Lieb
The Wave Nature of Light

The Wave Nature of Light
The Wave Nature of Light

The Wave Nature of Light
Light Wave nature of light.

Light Wave nature of light.
Snell’s Law Snell’s Law describes refraction as light strikes the boundary between two media n1 sin q1 = n2 sin q2 The index of refraction of a pure vacuum.

Snell’s Law Snell’s Law describes refraction as light strikes the boundary between two media n1 sin q1 = n2 sin q2 The index of refraction of a pure vacuum.
1 An Historical Review of Natural Phenomena and Models of Natural Phenomena and Models That Demonstrates Wave-Particle Duality.

1 An Historical Review of Natural Phenomena and Models of Natural Phenomena and Models That Demonstrates Wave-Particle Duality.
Review. The Wave Nature of Light Important: When a light wave travels from one medium to another, its frequency does not change, but its wavelength does.

Review. The Wave Nature of Light Important: When a light wave travels from one medium to another, its frequency does not change, but its wavelength does.
Lecture 12 Light: Reflection and Refraction Chapter 22.1  22.4 Outline History of Studies of Light Reflection of Light The Law of Refraction. Index of.

Lecture 12 Light: Reflection and Refraction Chapter 22.1  22.4 Outline History of Studies of Light Reflection of Light The Law of Refraction. Index of.
Chapter 34 The Wave Nature of Light; Interference

Chapter 34 The Wave Nature of Light; Interference
PA2001: Time and Energy Waves and Interference Light as a wave Fermat’s principle Reflection Refraction Thin Film.

PA2001: Time and Energy Waves and Interference Light as a wave Fermat’s principle Reflection Refraction Thin Film.
Lecture 33 Review for Exam 4 Interference, Diffraction Reflection, Refraction.

Lecture 33 Review for Exam 4 Interference, Diffraction Reflection, Refraction.
Phy 212: General Physics II Chapter 35: Interference Lecture Notes.

Phy 212: General Physics II Chapter 35: Interference Lecture Notes.
Lecture 3 – Physical Optics

Lecture 3 – Physical Optics
Chapter 35 Interference (cont.).

Chapter 35 Interference (cont.).
Physics for Scientists and Engineers II, Summer Semester 2009 1 Lecture 22: July 15 th 2009 Physics for Scientists and Engineers II.

Physics for Scientists and Engineers II, Summer Semester Lecture 22: July 15 th 2009 Physics for Scientists and Engineers II.
Vocabulary Review Properties of Waves The Electromagnetic Spectrum

Vocabulary Review Properties of Waves The Electromagnetic Spectrum

Similar presentations

Ads by Google