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Light Refraction

Presented by: Vandana Bathla & Eric Williams. Light Refraction. Light Refraction. Have you ever wondered why it appears we see puddles of water on a highway on a hot summer day? What you are seeing is not really water, but a mirage. Mirages work on the concept of refraction.

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Light Refraction

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  1. Presented by: Vandana Bathla & Eric Williams Light Refraction

  2. Light Refraction • Have you ever wondered why it appears we see puddles of water on a highway on a hot summer day? • What you are seeing is not really water, but a mirage. • Mirages work on the concept of refraction. • There are many more real-life phenomenon that occur due to refraction. Ex. Bending of pencil underwater, etc…

  3. What Causes Light Refraction? • Well, quite simply, refraction is the bending of a light wave as it enters a medium where it’s speed is different. • As the speed of light decreases through the slower medium the wavelength is also shortened. Frequency remains constant.

  4. Lesson Sequence • Lesson 1: Refraction • Defining Refraction • Lesson 2: Snell’s Law • Explain the calculations involved • Lesson 3: Critical Angles • Lesson 4: Problem Solving • Problems involving Snell’s law

  5. Curriculum Expectations • E2.1 use appropriate terminology related to light and optics, including, but not limited to: angle of incidence, angle of reflection, angle of refraction, centre of curvature, focal length, luminescence, magnification, principal axis, radius of curvature, and vertex [C] • E2.3 use an inquiry process to investigate the refraction of light as it passes through a variety of media (e.g., the angles of incidence and refraction as light passes through a clear acrylic block) [PR] • E2.4 use an inquiry process to investigate the refraction of light as it passes through media of different refractive indices, compile data on their findings, and analyze the data to determine if there is a trend (e.g., the amount by which the angle of refraction changes as the angle of incidence increases varies for media of different refractive indices) [PR, AI, C] • E2.6 calculate, using the indices of refraction, the velocity of light as it passes through a variety of media, and explain the angles of refraction with reference to the variations in velocity [PR, C] • E3.4 explain the conditions required for partial reflection/refraction and for total internal reflection in lenses, and describe the reflection/refraction using labeled ray diagrams • E3.4 explain the conditions required for partial reflection/refraction and for total internal reflection in lenses, and describe the reflection/refraction using labeled ray diagrams

  6. Teaching Approach • The following activity will be used to show the students an example of refraction. • The opening activity will also be used to facilitate greater student interest about refraction. • Opening Activity “Hook”: • Students will look at a glass of water and analyze the angles in which an object changes and answer questions related to mirages. • Scientific Investigation Lab: • “Spear Fishing” – Students will look at the practical applications of applying refraction into everyday situations. • Historical connections to this lab can also be made to history/geography where the student performs a the role of an 18th century hunter that needs to feed his/her family. What measures would you introduce to ensure that you caught the fish using your spear? • Students will create a lab using the framework of “Smarter Science” to formulate their data collection and observational techniques.

  7. Spear Lab • Students will use a spear (long wood stick, blunted approx 1 meter) to hit a wooden fish tied to a block and placed in a body of water • For convenience purposes, a stream, lake, pool…etc. Can be used. Understandably different schools will have access to different materials. • Students will create a lab write up with their attempts to hit the fish underwater. Data will be recorded and collaborated with the rest of the class.

  8. Practical Applications • Students will make connections to the world and the environment through these activities. • Firstly: Connections to the fishing industries that rely on the scientific principals of refraction for navigation and catching food. • Secondly: Environmental connections to predatory animals such as bears that need to compensate for refraction to catch fish from a stream.

  9. Practical Applications Contd. • After the lessons, the students will be divided into groups containing no more than 4 people. • Each group will be given a real-life scenario such as mirages, the sparkle of diamonds, fiber optics, etc. • The students will then be asked to explain how refraction causes all these real-life scenarios. • The students may ask for hints.

  10. Potential Student Difficulties • Without some familiarity with the properties of light, students are not expected to fully grasp the concept of refraction . • Students might have difficulties with the sine law because they will be using it for the first time. • The potential student difficulties in understanding refraction could be linked with their common misconceptions about the concept of light like: • The distance light travels is dependent on its energy. • That the rays are parallel implies obligatorily that this is the privileged direction; and it is generally a horizontal direction. • Shadows are formed when light is stopped by objects, but students think that shadows can be conceived as an image, or as something belonging to an object • Students think that the eyes send out something making it possible for us to see. • Light always passes straight through transparent material (without changing direction). • We can see because light travels to your eyes and then from the eyes to the object. • Light travels from the eyes to the object.

  11. Possible Solutions • Practice using ray diagrams • Provide contradictions to students' misconceptions through questions, implications, and demonstrations. • Encourage discussion, urging students to apply physical concepts in their reasoning. • Foster the replacement of the misconception with new concepts through (i) questions, (ii) thought experiments, (iii) hypothetical situations with and without the underlying physical law, (iv) experiments or demonstrations designed to test hypotheses. • Re-evaluate students' understanding by posing conceptual questions • Provide a lot of practice problems involving sine law

  12. Safety Implications • As within any lab experiment, caution must be taken regarding the use of equipment and other materials. • When working with light refraction, specifically in the ‘Spear Activity’ the following precautionary measures should be taken: • Ensure all students have read the lab safety document outlined at the beginning of the year. • The use of water and other liquid materials has a proclivity for spilling. Therefore, closed toed shoes are to be worn in the lab. • Potential hazard for slipping as well. • List of harmful substances should be known to students along with awareness of safety procedures and MSDS sheet locations.

  13. Practical Implications • Refraction causes many illusions, one of them being the apparent depth of objects submerged in water. • A second natural phenomena caused by refraction is the appearance of mirages. A mirage occurs when refracted light appears as if it were reflected light. • The concept of refraction is also used in special fiber optics wire.

  14. Differentiated Instruction • Students will be given all labs at the beginning of the class to allow more time for review of the worksheets. • Digital media presentations using power-point, videos, blogs, and pictures will be illustrated to supplement verbal teaching for visual/spatial learners • Kinesthetic movement activities will be randomized to engage students. • Extra time will be given for identified students in completion of labs and unit tests. • Partnering and group collaboration will be encouraged.

  15. Differentiated Assessment • Diagnostic: • Opening activities at the beginning of each lesson will be used to interpret and activate prior knowledge regarding light refraction. • Formative: • Questions within the labs are going to be asked as open-ended to engage more critical thinking and inquiry based processing. • Students are encouraged to critique the labs and current research to maintain a “critical lens”. • Summative: • A summative test can be created at the end of the unit which contains questions satisfying all areas of the achievement chart to evaluate the students understanding of light refraction.

  16. Annotated References • Bosack, S.V. (2000). Science Is. A source book of fascinating facts, projects and activities. Scholastic Canada Ltd, pg 62-63. • Ontario Ministry of Education (2010). Growing Success: Assessment, Evaluation and Reporting in Ontario Schools, First Edition. Queen’s Printer for Ontario. • Ontario Ministry of Education (2008). The Ontario Curriculum Grades 9-10 Science. • Youth Science Canada. (2011). Smarter Science: Introducing the Framework. • Activity Links • http://www.ankn.uaf.edu/publications/Alaska_Science/Spear.html • http://hyperphysics.phy-astr.gsu.edu/hbase/geoopt/refr.html#c3

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