Q ~ ~ ~ ~ # $ ~ ( 3 0 %... 1. (5%)

... the first and third perpendicular to each other. What angle should the polarizing direction of the middle sheet make with the polarizing direction of the first sheet to obtain maximum transmitted intensity when unpolarized light is incident on the stack? (4) (in degrees) ...

Chapter 6 Experiment 4: Wave Interference

Course Outline - Pima Community College

... D. Examples and applications of simple harmonic motion E. Simple harmonic motion and uniform circular motion Wave Motion A. The dynamics of wave motion and the wave equation B. Solutions to the wave equation: traveling waves C. Types of mechanical waves: longitudinal and transverse D. Wave speed, wa ...

Optics6 - Cbsephysicstutorials

... and sound waves can bend around obstacles, how is it that the students are unable to see each other even though they can converse easily. Ray optics is based on the assumption that light travels in a straight line. Diffraction effects (observed when light propagates through small apertures/slits or ...

Quiz3 - 203 .tst

... C) equally divided between the magnetic and the electric fields. D) zero. Answer: C 10) If the magnetic field in a traveling electromagnetic wave has a maximum value of 16.5 nT, what is the maximum value of the electric field associated with it? A) 4.95 ˛ 10-1 V/m B) 55.0 ˛ 10-16 V/m C) 49.5 ˛ 10-1 ...

MICROWAVE AND LIGHT INTERFERENCE - Galileo

... proportional to the square of the net electric field. The intensity (what we can observe) is the time average of the energy density. Important Note: To find the intensity of the electromagnetic waves at any point, we must first add up (as vectors, of course), all of the electric fields to find the n ...

NA 2nd Semester Review Regular Physics No Ans

... 9. If you know the wavelength of any form of electromagnetic radiation, you can determine its frequency because a. all wavelengths travel at the same speed. b. the speed of light varies for each form. c. wavelength and frequency are equal. d. the speed of light increases as wavelength increases. ...

Matter-wave interferometry: towards antimatter interferometers

... extended source (transverse size σs ) illuminates an N -slit grating G (period D and slit width a) from a distance ys . ...

Final Exam - University of Louisville Physics

... PHYS 222 – Spring 2012 – Final Exam Closed books, notes, etc. No electronic device except a calculator. ...

To determine the wavelength of a monochromatic source of light

... 2. Light source and slit is arranged in order to get the maximum light incident on the slit. 3. The centre of slit, biprism and eye piece is arranged at same height as shown in Figure.1. 4. The slit and biprism edge are made vertical and in line parallel to the bench. 5. Observe the interference fri ...

Name:

... A well-aligned optical communication system with high quality optics is said to be diffraction-limited, which means that errors are unlikely EXCEPT for those caused by diffraction, which can’t really be stopped because it is inherent in the wave nature of light. ...

Lecture 32 - McMaster Physics and Astronomy

1) Velocity is a vector quantity that has both magnitude and direction

... 86) Period is inversely proportional to frequency. As period increases, frequency decreases. ( T = 1/f) The product of period and frequency is 1. 87) Period, velocity and wavelength are directly proportional to one another. If the period doubles, or the velocity doubles the wavelength also doubles. ...

Chapter24

In the figure shown above, an object is placed a distance in front of a

PPT

... The force F is proportional to the area A. ...

Last Name - Saint Demetrios Astoria School

... A ray of monochromatic light having a frequency of 5.09 x 1014 Hertz is incident on an interface of air and corn at an angle of 35 degrees as shown below. The ray is transmitted through parallel layers of corn oil and glycerol and is then reflected from the surface of a plane mirror, located below a ...

Phy107Fall06Lect15 - UW High Energy Physics

Document

... The upper wave travels one-half of a wavelength farther than the lower wave to reach point R The trough of the bottom wave overlaps the crest of the upper wave This is destructive interference ...

Fig. 35-2

... The concept of optical interference is critical to understanding many natural phenomena, ranging from color shifting in butterfly wings to intensity patterns formed by small apertures. These phenomena cannot be explained using simple geometrical optics, and are based on the wave nature of light. In ...

Electromagnetic Waves

... This is the exception to the rule that says that all waves in a given medium travel at the same speed (we learned this for sound waves in a previous chapter). In a material medium, EM waves exhibit a phenomenon called DISPERSION, where the index of refraction depends on the frequency of the light. H ...

A Brief History of Planetary Science

$Diffracting fractals: new paradigms in linear wave physics$

Diffracting fractals: new paradigms in linear wave physics

... Figure 5: Diffraction of the Weierstrass fractal function [Eq. (1)] with random phases for different values of the dimension D at a single slit when D = 1.99. (a) NF = 5, (b) NF = 10, (c) NF = 30, (d) NF = 50. Other parameters:  = 1.2, /a = 1.0, L/k = 1, and  = 0.1. Shaded areas denote geometric ...

The Michelson Interferometer

... between two beams of light. A diagram of the apparatus is shown in Fig. 1. The basic operation of the interferometer is as follows. Light from a light source is split into two parts. One part of the light travels a different path length than the other. After traversing these different path lengths, ...

The Michelson Interferometer

... produce optical interference. These instruments are grouped under the generic name of interferometers. The Michelson interferometer causes interference by splitting a beam of light into two parts. Each part is made to travel a different path and brought back together where they interfere according t ...

< 1 ... 59 60 61 62 63 64 65 66 67 ... 82 >

Diffraction

Diffraction refers to various phenomena which occur when a wave encounters an obstacle or a slit. In classical physics, the diffraction phenomenon is described as the interference of waves according to the Huygens–Fresnel principle. These characteristic behaviors are exhibited when a wave encounters an obstacle or a slit that is comparable in size to its wavelength. Similar effects occur when a light wave travels through a medium with a varying refractive index, or when a sound wave travels through a medium with varying acoustic impedance. Diffraction occurs with all waves, including sound waves, water waves, and electromagnetic waves such as visible light, X-rays and radio waves.Since physical objects have wave-like properties (at the atomic level), diffraction also occurs with matter and can be studied according to the principles of quantum mechanics. Italian scientist Francesco Maria Grimaldi coined the word ""diffraction"" and was the first to record accurate observations of the phenomenon in 1660.While diffraction occurs whenever propagating waves encounter such changes, its effects are generally most pronounced for waves whose wavelength is roughly comparable to the dimensions of the diffracting object or slit. If the obstructing object provides multiple, closely spaced openings, a complex pattern of varying intensity can result. This is due to the addition, or interference, of different parts of a wave that travels to the observer by different paths, where different path lengths result in different phases (see diffraction grating and wave superposition). The formalism of diffraction can also describe the way in which waves of finite extent propagate in free space. For example, the expanding profile of a laser beam, the beam shape of a radar antenna and the field of view of an ultrasonic transducer can all be analyzed using diffraction equations.

Top subcategories

Top subcategories

Top subcategories

Top subcategories

Top subcategories

Top subcategories

Top subcategories

Top subcategories

Diffraction