Waves and Optics - Science - 10th Grade.pptx

The Behaviour of Light Here is where your presentation begins Class: SS3 Date Subject: Physics

Learning Objectives Infrared rays, visible rays, ultraviolet rays, x-rays, gamma rays Understaanding spectroscopy Examples of EM examples applications 01. 02. 03.

EM waves in the EM Spectrum 01.

Infrared Rays What is Light? Light is a type of electromagnetic wave. Electromagnetic waves Electromagnetic waves are waves that can travel through the vacuum of outer space. Unlike sound waves, which need a medium (like air or water) to travel through, electromagnetic waves do not require a medium . They are created by the movement of electric charges and are composed of oscillating electric and magnetic fields.

Introduction to Light waves continued Properties of Light Speed: Light travels approximately 300,000 kilometres per second (km/s) in a vacuum . Wavelength: The distance between consecutive peaks of the wave. Visible light has wavelengths between 400 nm (nanometers) and 700 nm . Frequency: The number of wave peaks that pass a point in one second. It's measured in Hertz (Hz).

Intro to Light waves cont’d Visible Light This is the light we can see with our eyes. It includes all the colors of the rainbow . Each color corresponds to a different wavelength, with red having the longest wavelength and violet having the shortest. The Electromagnetic spectrum The electromagnetic spectrum includes all types of electromagnetic waves, ranging from very long wavelength radio waves to very short wavelength gamma rays. Visible light is a small part of this spectrum, which includes red (longest wavelength) to violet (shortest wavelength).

Electromagnetic Spectrum

Electromagnetic spectrum Type of radiation Wavelength (pm) Frequency (hertz) Energy (joules) Radio waves > 1 x 10^5 pm < 3 x 10^9 Hz < 2 x 10^-24 J Microwaves 1 mm - 1 m 3 x 10^9 Hz - 3 x 10^11 Hz 2 x 10^-24 J - 2 x 10^-22 J Infrared 700 nm - 1 mm 3 x 10^11 Hz - 4.3 x 10^14 Hz 2 x 10^-22 J - 2.9 x 10^-19 J Visible light 400 nm - 700 nm 4.3 x 10^14 Hz - 7.5 x 10^14 Hz 2.9 x 10^-19 J - 5 x 10^-19 J Ultraviolet 10 nm - 400 nm 7.5 x 10^14 Hz - 3 x 10^16 Hz 5 x 10^-19 J - 2 x 10^-17 J X-rays 0.01 nm - 10 nm 3 x 10^16 Hz - 3 x 10^19 Hz 2 x 10^-17 J - 2 x 10^-14 J Gamma rays < 0.01 nm > 3 x 10^19 Hz > 2 x 10^-14 J

Principle of Reflection 02. Definition Law of Reflection Illustration and Implementations

Law of Reflection The Law of Reflection states that when a light ray hits a smooth surface, the angle of incidence (the angle between the incoming ray and the normal to the surface) is equal to the angle of reflection (the angle between the reflected ray and the normal). Definition Mathematical representation

Illustration of Law of Reflection The incident ray, the reflected ray, and the normal (a line perpendicular to the surface at the point of incidence) all lie in the same plane.

Implementation of The Law of Reflection Plane Mirror Periscope

Principle of Refraction 03. What is Refraction? Snell’s Law

Law of Refraction Here, and are the refractive indices of the two media, and and are the angles of incidence and refraction, respectively. The refractive index is a measure of how much the speed of light is reduced inside the medium . NOTE: The incident angle is the angle between the incident ray and the normal to the surface while the refracted angle is the angle between the refracted ray and the normal The Law of Refraction, also known as Snell's Law, states that when a light ray passes from one medium into another, it bends or refracts. Snell’s Law Mathematical representation What is Refraction? This is the bending of a light ray as it crosses the boundary between two media of different densities, thus causing a change in its direction.

Illustration of The Law of Refraction Plane Mirror Periscope

Implementation of The Law of Refraction Lens Prism

Principle of Diffraction 04. What is Diffraction? Conditions for Diffraction

What is Diffraction? Diffraction Pattern: When light passes through a single slit, it creates a central bright fringe (or band) with several dimmer fringes on either side. The pattern results from the interference of the light waves spreading out after passing through the slit . Double-Slit Experiment: In a double-slit experiment, light passing through two close slits creates an interference pattern of alternating bright and dark fringes on a screen. This is due to constructive and destructive interference of the light waves emanating from the two slits. Wave Behavior: Diffraction demonstrates the wave nature of light. When light encounters an obstacle or a slit that is comparable in size to its wavelength, it bends around the edges and creates patterns of light and dark regions. Definition Diffraction is the bending and spreading out of light waves as they pass around an obstacle or through a narrow slit

Condition for Diffraction As a general rule: If wavelength > obstacle/aperture size: Strong diffraction If wavelength ≈ obstacle/aperture size: Moderate diffraction If wavelength < obstacle/aperture size: Minimal diffraction For a slit or aperture, the condition for observing a clear diffraction pattern is often given by : Where: a = width of the slit or aperture λ = wavelength of the wave Significant diffraction occurs when the wavelength is comparable to or larger than the size of the obstacle or aperture . For obstacles, a similar condition applies. Diffraction effects become noticeable when the size of the obstacle is comparable to or smaller than the wavelength. The conditions for diffraction depend on the relationship between the wavelength of the wave and the size of the obstacle or aperture it encounters. Here are the key points:

Illustration of Diffraction The angle of diffraction (θ) is related to the wavelength and aperture size by the equation: This shows that longer wavelengths and smaller apertures lead to larger diffraction angles.

More things to note on diffraction… All electromagnetic waves can bend (diffract) to some degree, regardless of their wavelength. The key is the relationship between the wavelength and the size of the obstacle or aperture. Waves with longer wavelengths (like radio waves) diffract more noticeably around everyday objects . While Waves with shorter wavelengths (like visible light, X-rays, gamma rays) require much smaller obstacles or apertures to show noticeable diffraction effects. For example: Radio waves (long wavelength) diffract noticeably around buildings. Visible light (shorter wavelength) diffracts noticeably around the edge of a razor blade or through a narrow slit. X-rays (very short wavelength) diffract noticeably when passing through a crystal lattice. .01 .02 .03

Principle of Interference 05. What is Interference? Types of Interference Coherent Sources Young’s Double-slit Experiment Conditions for Light Interference

What is Interference? Definition Interference is the phenomenon in which two waves superpose to form the resultant wave of the lower, higher or same amplitude. The most commonly seen interference is the optical interference or light interference. This is because light waves are generated randomly by most of the sources. This means that light waves coming out of a source do not have a constant amplitude, frequency or phase. The most common example of interference of light is the soap bubble which reflects wide colours when illuminated by a light source.

Types of Interference In destructive interference, the crest of one wave falls on the trough of another wave such that the amplitude is minimum. The displacement and phase of these waves are not the same. Constructive interference Constructive interference takes place when the crest of one wave falls on the crest of another wave such that the amplitude is maximum. These waves will have the same displacement and are in the same phase. Destructive interference

Illustration of The Law of Refraction

Coherent Sources Definition Two sources are said to be coherent when the waves emitted from them have the same frequency and constant phase difference. Examples of coherent sources are: Laser light is an example of a coherent source of light. The light emitted by the laser light has the same frequency and phase. Sound waves are another example of coherent sources. The electrical signals from the sound waves travel with the same frequency and have constant phase difference. Characteristics The waves generated have a constant phase difference The waves are of a single frequency Illustration of coherent sources

Young’s Double-Slit Experiment The great scientist Young performed an experiment to prove the wave nature of light by explaining the phenomenon of interference of light. In Young’s double slit experiment, two coherent sources were generated using diffracted light from a single slit. Note that the waves must have a constant phase difference, so the two slits need not be placed symmetrically from the first slit to observe an interference pattern.

Conditions for Interference of Light Waves For sustained interference of light to occur, the following conditions must be met: Coherent sources of light are needed. Amplitudes and intensities must be nearly equal to produce sufficient contrast between maxima and minima. The source must be small enough that it can be considered as a point source of light. The interfering sources must be near enough to produce wide fringes. The source and screen must be far enough to produce wide fringes. The sources must emit light in the same state of polarization. The sources must be monochromatic.

Polarization and Doppler Effect 06. What is Polarization? Types of Polarization Methods used in Light Polarization Applications What is Doppler Effect?

What is polarization? Light is the interaction of electric and magnetic fields travelling through space. The electric and magnetic vibrations of a light wave occur perpendicularly to each other. The electric field moves in one direction and the magnetic field in another ‘perpendicular to each other. So, we have one plane occupied by an electric field, another plane of the magnetic field perpendicular to it, and the direction of travel is perpendicular to both. These electric and magnetic vibrations can occur in numerous planes. A light wave that is vibrating in more than one plane is known as unpolarized light. The light emitted by the sun, by a lamp or a tube light are all unpolarised light sources. As you can see in the image below, the direction of propagation is constant, but the planes on which the amplitude occurs are changing.

What is polarization? Polarized waves are light waves in which the vibrations occur in a single plane. Plane polarized light consists of waves in which the direction of vibration is the same for all waves. In the image above, you can see that a plane polarized light vibrates on only one plane. The process of transforming unpolarized light into polarized light is known as polarization . The devices like the polarizers you see are used for the polarization of light.

Types of Polarization There are two linear components in the electric field of light that are perpendicular to each other such that their amplitudes are equal, but the phase difference is π/2. The propagation of the occurring electric field will be in a circular motion. Linear Polarization In linear polarization, the electric field of light is limited to a single plane along the direction of propagation Circular Polarization Elliptical Polarization The electric field of light follows an elliptical propagation. The amplitude and phase difference between the two linear components are not equal.

Methods used in The Polarization of Light Polarization by Transmission Polarization by Reflection Polarization by Scattering Polarization by Refraction

Applications of Polarization It is used in sunglasses to reduce the glare. Polaroid filters are used in plastic industries for performing stress analysis tests. Three-dimensional movies are produced and shown with the help of polarization It is used for differentiating between transverse and longitudinal waves . Infrared spectroscopy uses polarization It is used in seismology to study earthquakes In Chemistry, the chirality of organic compounds is tested using polarization techniques

What is Doppler Effect? Doppler effect or Doppler shift is a phenomenon that is observed whenever the source of waves is moving with respect to an observer. For example, an ambulance crossing you with its siren blaring is a common physical demonstration of the Doppler Effect . The Doppler effect or the Doppler shift describes the changes in the frequency of any sound or light wave produced by a moving source with respect to an observer . Christian Johann Doppler first proposed the Doppler Effect (Doppler Shift) in 1842.

What is Doppler Effect? When the light source moves away from the observer, the frequency received by the observer will be less than the frequency transmitted by the source. This causes a shift towards the red end of the visible light spectrum. Astronomers call it the redshift . When the light source moves towards the observer, the frequency received by the observer will be greater than the frequency transmitted by the source. This causes a shift towards the high-frequency end of the visible light spectrum. Astronomers call it the blue shift .

Alternative resources Here’s an assortment of alternative resources whose style fits that of this template: Photos Gradient abstract background

Types of waves Mechanical waves Transverse waves Electromagnetic waves Longitudinal waves Despite being red, Mars is actually a cold place. It’s full of iron oxide dust Earth is the third planet from the Sun and harbors life Jupiter is a gas giant and the biggest planet in the Solar System Saturn is the second-largest planet in the Solar System

Venus has extremely high temperatures Neptune is the farthest planet from the Sun Wave parameters Mars is actually a very cold place Mercury is the closest planet to the Sun Saturn is a gas giant and has several rings Jupiter is the biggest planet of them all Crest Compression Phase velocity Interference Polarization Doppler effect

Awesome words

A picture is worth a thousand words

A picture always reinforces the concept Images reveal large amounts of data, so remember: use an image instead of a long text. Your audience will appreciate it

98,300,000 Big numbers catch your audience’s attention

Jupiter’s rotation period 9h 55m 23s 333,000 The Sun’s mass compared to Earth’s 386,000 km Distance between Earth and the Moon

Applications of this branch of optics Mercury is the closest planet to the Sun and the smallest of them all Application 01 Venus has a beautiful name and is the second planet from the Sun Application 02 Despite being red, Mars is actually a cold place. It’s full of iron oxide dust Application 03 50% 75% 25%

Computer mockup You can replace the image on the screen with your own work. Just right-click on it and select “Replace image”

Tablet mockup You can replace the image on the screen with your own work. Just right-click on it and select “Replace image”

Phone mockup You can replace the image on the screen with your own work. Just right-click on it and select “Replace image”

Research laboratories Mercury is the closest planet to the Sun and the smallest of them all Laboratory 01 Venus has a beautiful name and is the second planet from the Sun Laboratory 02 Despite being red, Mars is actually a cold place. It’s full of iron oxide dust Laboratory 03

Historical experiments in optics Venus is the second planet from the Sun The Sun is the star at the center of the Solar System Jupiter is the biggest planet in the Solar System Mercury is the smallest planet in the Solar System XXXX XXXX XXXX XXXX

Refraction in a triangular prism Virtual image of light source Spot light source Decomposition of white light into spectral colors

Electromagnetic spectrum Type of radiation Wavelength (pm) Frequency (hertz) Energy (joules) Radio waves > 1 x 10^5 pm < 3 x 10^9 Hz < 2 x 10^-24 J Microwaves 1 mm - 1 m 3 x 10^9 Hz - 3 x 10^11 Hz 2 x 10^-24 J - 2 x 10^-22 J Infrared 700 nm - 1 mm 3 x 10^11 Hz - 4.3 x 10^14 Hz 2 x 10^-22 J - 2.9 x 10^-19 J Visible light 400 nm - 700 nm 4.3 x 10^14 Hz - 7.5 x 10^14 Hz 2.9 x 10^-19 J - 5 x 10^-19 J Ultraviolet 10 nm - 400 nm 7.5 x 10^14 Hz - 3 x 10^16 Hz 5 x 10^-19 J - 2 x 10^-17 J X-rays 0.01 nm - 10 nm 3 x 10^16 Hz - 3 x 10^19 Hz 2 x 10^-17 J - 2 x 10^-14 J Gamma rays < 0.01 nm > 3 x 10^19 Hz > 2 x 10^-14 J

You can use this graph Follow the link in the graph to modify its data and then paste the new one here. For more info, click here Period 01 Period 02 XXXX 47% 28% XXXX 10% 12% XXXX 30% 21% XXXX 14% 85%

Kaliyah Harris Sofia Hill Our team You can speak a bit about this person here You can speak a bit about this person here

Uses of optics in everyday life Uses of optics in everyday life Glasses and lenses Microscopes and telescope Optical fibers Spectroscopy Absorption spectroscopy Spectroscopy in astronomy Nuclear magnetic resonance spectroscopy (NMR)

Types of reflection Specular reflection Diffuse reflection

Electromagnetic spectrum Gamma ray X-ray Ultraviolet Infrared Microwave Radio Higher energy Lower energy

Activity 1: select the correct answers 01 In regular reflection, the reflected image will be… A. Clear B. Fuzzy C. Distorted D. Upside down 02 The waves with the longest wavelength and the lowest frequency are… A. Infrared B. Ultraviolet C. Radio waves D. X-rays 03 The amount of light that enters the eye is controlled by the… A. Iris B. Retine C. Cornea D. Leens 04 The color that has the longest wavelength is… A. Blue B. Green C. Red D. Orange

Activity 2: questions and answers What is refraction? What is the role of light in photosynthesis? How long does it take for sunlight to reach Earth? What is the branch of science that studies light?

Activity 3: true or false T F Animals can see light that humans cannot Nothing moves faster than light Light can move in a vacuum A rainbow is caused by the reflection of light off the Moon’s surface A magnifying glass can make objects appear smaller

Activity 4: match the concepts Reflection Refraction Prism Diffraction Optics The study of light and its behavior The bending of a wave around an obstacle or through a slit The reflection of light on a polished surface The change in the direction of light when it passes from one medium to another A crystal that separates light into its component colors

Thanks! Do you have any questions? [email protected] +34 654 321 432 yourwebsite.com Please keep this slide for attribution

Alternative resources Here’s an assortment of alternative resources whose style fits that of this template: Photos Gradient abstract background

Did you like the resources on this template? Get them on these websites: Photos Blurred night lights Blurred night lights ll Light rays in prism Vectors Gradient abstract background Gradient abstract background ll Resources

Instructions for use If you have a free account, in order to use this template, you must credit Slidesgo by keeping the Thanks slide. Please refer to the next slide to read the instructions for premium users. As a Free user, you are allowed to: Modify this template. Use it for both personal and commercial projects. You are not allowed to: Sublicense, sell or rent any of Slidesgo Content (or a modified version of Slidesgo Content). Distribute Slidesgo Content unless it has been expressly authorized by Slidesgo. Include Slidesgo Content in an online or offline database or file. Offer Slidesgo templates (or modified versions of Slidesgo templates) for download. Acquire the copyright of Slidesgo Content. For more information about editing slides, please read our FAQs or visit our blog: https://slidesgo.com/faqs and https://slidesgo.com/slidesgo-school

As a Premium user, you can use this template without attributing Slidesgo or keeping the Thanks slide. You are allowed to: Modify this template. Use it for both personal and commercial purposes. Hide or delete the “Thanks” slide and the mention to Slidesgo in the credits. Share this template in an editable format with people who are not part of your team. You are not allowed to: Sublicense, sell or rent this Slidesgo Template (or a modified version of this Slidesgo Template). Distribute this Slidesgo Template (or a modified version of this Slidesgo Template) or include it in a database or in any other product or service that offers downloadable images, icons or presentations that may be subject to distribution or resale. Use any of the elements that are part of this Slidesgo Template in an isolated and separated way from this Template. Register any of the elements that are part of this template as a trademark or logo, or register it as a work in an intellectual property registry or similar. For more information about editing slides, please read our FAQs or visit our blog: https://slidesgo.com/faqs and https://slidesgo.com/slidesgo-school Instructions for use (premium users)

This presentation has been made using the following fonts: Encode Sans Bold ( https://fonts.google.com/specimen/Encode+Sans ) Dm Sans Regular ( https://fonts.google.com/specimen/DM+Sans ) #041b2d #f8f8f8 #c375da #f58acb #ff9736 #ff6d6d Fonts & colors used

Create your Story with our illustrated concepts. Choose the style you like the most, edit its colors, pick the background and layers you want to show and bring them to life with the animator panel! It will boost your presentation. Check out h ow it works . Storyset Pana Amico Bro Rafiki Cuate

You can easily resize these resources without losing quality. To change the color , just ungroup the resource and click on the object you want to change. Then, click on the paint bucket and select the color you want. Group the resource again when you’re done. You can also look for more infographics on Slidesgo. Use our editable graphic resources...

JANUARY FEBRUARY MARCH APRIL PHASE 1 Task 1 Task 2 JANUARY FEBRUARY MARCH APRIL MAY JUNE PHASE 1 PHASE 2 Task 1 Task 2 Task 1 Task 2

You can resize these icons without losing quality. You can change the stroke and fill color ; just select the icon and click on the paint bucket/pen . In Google Slides, you can also use Flaticon’s extension , allowing you to customize and add even more icons. ...and our sets of editable icons

Educational Icons Medical Icons

Business Icons Teamwork Icons

Help & Support Icons Avatar Icons

Creative Process Icons Performing Arts Icons

Nature Icons

SEO & Marketing Icons

Waves and Optics - Science - 10th Grade.pptx

About This Presentation

Slide Content

Tags

Categories

Download

Quick Actions

Statistics

Related Slideshows

Waves and Optics - Science - 10th Grade.pptx

About This Presentation

Slide Content

Slide 1

Slide 2

Slide 3

Slide 4

Slide 5

Slide 6

Slide 7

Slide 8

Slide 9

Slide 10

Slide 11

Slide 12

Slide 13

Slide 14

Slide 15

Slide 16

Slide 17

Slide 18

Slide 19

Slide 20

Slide 21

Slide 22

Slide 23

Slide 24

Slide 25

Slide 26

Slide 27

Slide 28

Slide 29

Slide 30

Slide 31

Slide 32

Slide 33

Slide 34

Slide 35

Slide 36

Slide 37

Slide 38

Slide 39

Slide 40

Slide 41

Slide 42

Slide 43

Slide 44

Slide 45

Slide 46

Slide 47

Slide 48

Slide 49

Slide 50

Slide 51

Slide 52

Slide 53

Slide 54

Slide 55

Slide 56

Slide 57

Slide 58

Slide 59

Slide 60

Slide 61

Slide 62

Slide 63

Slide 64

Slide 65

Slide 66

Slide 67

Slide 68

Slide 69

Slide 70

Slide 71

Slide 72

Slide 73

Slide 74

Slide 75

Slide 76

Slide 77