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<td style="text-align: | <td style="text-align: left; width: 33%">[[K-12 Outreach Introduction|Previous Topic]]</td> | ||
<td style="text-align: center; width: 33%">[[Main_Page#K-12 Outreach Kits|K-12 Outreach Kits]]</td> | <td style="text-align: center; width: 33%">[[Main_Page#K-12 Outreach Kits and Labs|K-12 Outreach Kits and Labs]]</td> | ||
<td style="text-align: right; width: 33%">[[ | <td style="text-align: right; width: 33%">[[Photovoltaics- Outreach Kit|Next Topic]]</td> | ||
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== Overview == | |||
The purpose of this kit is to introduce students about the basic properties of light such as color, straight beams, reflection, refraction and polarization. Each of these phenomena can be presented in a “discovery” mode in which students related their current knowledge by guessing what will happen. At a higher level some of the phenomena can be explained with formulas and confirmed with measurements. Following each demo description are ideas of how to tie the demo into the CMDITR science. | |||
== User Guide == | |||
Key Concepts and Demos | |||
=== Diffraction Grating === | |||
<br clear='all'> | |||
[[Image:Diffraction fluorescent.jpg|thumb|300px|]] | |||
'''White light is composed of many colors.''' Pass around the diffraction grating. Have them describe what they see. Are the colors the same for any light you look at? The diffraction grating is able to split white light into colors that make it up. (The diffraction grating works because of constructive and destructive interference, but this is higher level concept.) Students may be able to notice that the colors difference between an incandescent bulb, and LED and fluorescent bulb shown below. Connect this idea to other sources of rainbows colors such as a rainbow (reflection and dispersion within a drop of water), oil sheen on water (interference between nanolayers), or prisms (transmission and dispersion). | |||
=== Additive Color Mixing === | |||
<br clear='all'> | |||
'''When red, green and blue are added together they produce white.''' Pass out the color flashlights. These produce red, green and blue light. What happens when two or more colors of light are combined? | |||
*A RGB monitor has tiny red, green and blue dots. All colors including white can be made by mixing these three colors. CMDITR research with organic light emitting diodes has led to OLED displays which use thousands of red, green and blue lights to make all the points on the display. | |||
[[Image:Colorflash.JPG|thumb|300px|left]] | |||
[[Image:800px-LCD RGB.jpg|thumb|300px|right]] | |||
<br clear='all'> | |||
=== Color filters === | |||
<br clear='all'> | |||
[[Image:Filterkit.JPG|thumb|300px|]] | |||
'''Light can be absorbed.''' Ask students what they know about color. | |||
a. Pass out colored filter samples and have students look at the room. Which color filter makes the light of a certain color go away? Colored filters absorb different colors and let other colors through. The deluxe filter paddle also has a polarizing filter and a diffraction grating. | |||
b. Ask which color paints are mixed together to make other colors. Is it possible to make white paint by mixing colored paints? (No this is because each color absorbs another part of the spectrum. If you added enough colors together eventually to would absorb all the light making black.) Have student pick three colors from the sample pack that when combined makes black or grey.If an organic solar cell appears red colored what does tell you about its absorption spectrum? The color of reflected light from a material represents the color of light that is not absorbed. | |||
c. Print out the “red reveal” hidden message sheets. Ask students to find a filter that reveals the hidden message. The red filter will mask all the colors that are similar to red in the picture. This makes cyan, blue and purple layer that shows up as black because light from these is blocked by the red filter. Red and yellow on the design show up as white when viewed through the red filter. You can also learn [[how to make a red reveal message]]. | |||
=== | <embed_document width="55%" height="600">http://depts.washington.edu/cmditr/media/redreveal.pdf</embed_document> | ||
<embed_document width="55%" height="600">http://depts.washington.edu/cmditr/media/redreveal2.pdf</embed_document> | |||
<embed_document width="55%" height="600">http://depts.washington.edu/cmditr/media/colorwheel.pdf</embed_document> | |||
*Reseach Connection Solar panels are black because they absorb many colors. We are trying to design new materials that can capture solar energy and convert the energy to electricity. We could make a blue solar cell. It would might pretty but it might not work as well as one that appears black. Why? | |||
=== Spectroscope === | |||
<br clear='all'> | |||
'''The color of light can be described by wavelength.''' You may not notice it but every light has its own unique color. A spectroscope is an instrument that lets you measure all the colors present in a light source. | |||
a. Point the spectroscope at a fluorescent light. Notice the green line that appears at the 5450 mark. Fluorescent bulbs are actually a little bit green. Some street lights are blue or even orange. This color depends on the chemistry of the materials used in the bulb. | |||
b. Now place a color filter #89 that only transmits color in the green part of the spectrum. Notice that the red line disappears from the fluorescent spectrum. Try using other filters to isolated different lines. What rule can you come up with about what color filters do to the full color spectrum of light? ( A color filter blocks all colors except for the color it appears to be. Similarly reflective colors absorb all light except for the color they can be observed to reflect) | |||
[[Image:Nasaspec.JPG|thumb|300px|]] | |||
* | *LED s have distinct colors. Scientists and engineers are working to make LEDs that have light with the full spectrum of sunlight so colors look right. Other applications require LEDs with a very specific wavelength to match the material they must pass through such as plastic screens or fiber optics. | ||
*We use instruments like the spectroscope to measure the light absorbed by chemicals we produce and to measure the light the color produce when they stimulated with lasers and electricity. | *We use instruments like the spectroscope to measure the light absorbed by chemicals we produce and to measure the light the color produce when they stimulated with lasers and electricity. | ||
<br clear='all'> | |||
=== UV sensitive beads === | |||
[[Image:30823-63ani.gif|thumb|300px|]] | |||
'''Some portions of the electromagnetic spectrum is invisible.''' Point out the colors on the electromagnetic spectrum chart and show that some types of radiation are not visible. Pass out some UV beads. These are photochromic beads which change color in the presence of UV light but revert to white in the dark. Ask students if all light is visible. Have them place the beads in various places around the classroom under lights, in the dark and in the sun. Explain that UV light is invisible but very powerful and is the cause of sun burns. | |||
*UV light is damaging to the body. It is also damaging to organic chemicals that we use in our solar cells. One of the challenges is to make design chemicals that do not break down in the presence of UV light. | |||
=== Glow Paper === | |||
[[Image:Glowpaper.png|thumb|300px|Phosphorescent paper is only excited by certain colors of light.]] | |||
*Optical fiber has smooth surfaces and narrow diameter. Light reflects inside the tube until it | '''Some materials absorb light and then continue to emit it over time. Some colors of light do not have enough energy to excite these substances.''' Turn off the lights in the room. Use the three colored flashlights, the white flashlight, daylight and the red laser to stimulate the glow-in-the dark paper. The red light should not be able to make it glow even though the laser pointer is very intense. This is because the chemical in the paper requires a minimum energy of light in order to excite its electrons to a higher energy level. Once the higher level is reached the energy slowly decays back to the ground state emitting light that is observed as glowing. | ||
*In photonics research we carefully match the color of light we are using excite a test substance with the chemical properties of the sample. | |||
=== Quantum Dots Solutions === | |||
[[Image:Quantumdots.png|thumb|300px|Quantum dot solutions in visible light above, and UV light below.]] | |||
'''Materials can be made that designed that absorb and emit radiation at specific wavelengths.''' | |||
These vials contain extremely small 2-5nm particles of cadmium selenium that have been grown to specific sizes because of their light absorbing qualities. These particles exhibit fluorescence; they absorb light at one color and emit light at a different wavelength. In the visible spectrum they absorb and emit yellow and pale red. They absorb ultraviolet and fluoresce in green, red and orange. | |||
a. Examine the vials in regular light. Predict what color the vials will appear under UV light. | |||
b. Expose the vials to UV light and discuss why this is different. | |||
*Research Connection: It is possible us quantum dots as a light antenna to absorb light and pass energy to another chemical. Some quantum dots for example could be used to trap infrared (IR ) light which would help solar cells work on cloudy days when IR passes through the clouds but visible light is mostly blocked. | |||
<br clear='all'> | |||
=== Electroluminescent Panel === | |||
Electricity can be used to excite a material and make it emit light. Electroluminescent panels have a transparent conductor layer, a layer of phosphor and a metal back electrode. When the front and back electrode are energized with a high frequency current the phosphor in between is stimulated and emits light. | |||
[[Image:ELpanels.jpg|thumb|300px|Electroluminescent panels with power supply]] | |||
*Research Connection: Electroluminescent panels are similar to the structure of Organic Light Emitting Diodes (OLEDs). Instead of a layer of phosphor the OLED contains an organic chemical that emits light after being excited with electricity. The organic chemicals can be tuned to get specific colors. OLEDs are now used for flat displays and televisions. | |||
<br clear='all'> | |||
=== Laser pointer === | |||
[[File:TIR in PMMA.jpg|thumb|A laser reflects within a piece of plastic]] | |||
'''Light goes in a straight line until it interacts with matter.''' All light sources produce beams of light. Lighting usually produces many beams going many directions. | |||
a. A laser produces a very bright, focused beam. Use the laser show the path of a light beam. Laser light is used to guide rockets, in surveying or carpentry to line things up, or even to guide farm machinery. Place the laser along a flat surface such as the floor or table and show that it is not affected by gravity. | |||
b. Fill the plastic tub with water and add some powdered milk powder to make the light beam visible. A tub of clear gelatin can also be used for this demonstration. | |||
=== Mirrors and lasers === | |||
<br clear='all'> | |||
[[Image:Laser_reflection.jpg|thumb|300px|]] | |||
'''Light can be reflected.''' First ask what kinds of objects reflect light. Test the theories about what will reflect by pointing the laser at the objects that are suggested. They should be able to describe the quality of shiny, glassy or metallic being needed for mirrors. Place a mirror on the block which is attached to a protractor. Place the cylinder lens end tip on the laser so that it produces flat line instead of a dot. Orient the line so it is vertical (with the cylindrical lens horizontal). This will make it easier to see the light ray and its reflection on the table. Use the protractor to measure the angle of light coming in (angle of incidence) and the angle of reflection. What is the rule for this? (the angle of incidence equals the angle of reflection) Challenge: what arrangement of mirrors would be needed to reflect a laser beam into a complete circle? Optical fiber has smooth surfaces and narrow diameter. Light reflects inside the tube until it emerges from the end. This is called total internal reflection. | |||
* a. We do many experiments with lasers that pass through many lenses, filters and sensors on a special optics table. We move the laser beam around the table using mirrors and large optical fibers. Some lasers are so powerful they can burn a hole in wood if the beam is absorbed. Mirrors can reflect this light without getting hot at all. | |||
=== Refraction with grow cubes and prisms === | |||
<br clear='all'> | |||
'''Light can be refracted.''' One day before the demonstration place several of the optic grow cubes into water in a plastic bag. Each cube will expand into a 3 cm, optically clear cube. Use the single edge razor to cut the cube into various shapes used in optics. Alternatively cast a sheet of clear gelatin using three times as much gelatin as is called for on the recipe. Use the laser pointer to show how lenses and prisms work. Try making a convex lens, a concave lens, an equilateral prism, a fiber optic tube, a periscope with right angle prisms. | |||
[[Image:Growcube.JPG|thumb|300px|left|Optic grow cubes]] | |||
[[Image:Cubesplit.png|thumb|300px|right|Prism shape]] | |||
[[Image:Cubeconvex.png|thumb|300px|left|Convex lens shape]] | |||
[[Image:Cubeconcave.png|thumb|300px|right|Concave lens shape]] | |||
<br clear='all'> | |||
Use the acrylic prism set to demonstrate various optics phenomena. If possible use two lasers to show parallel beams. | |||
[[Image:Lenskit.jpg|thumb|400px|left|Equilateral prism, plano convex, double concave, double convex and square prisms shapes.]] | |||
[[Image:Lens1.jpg|thumb|400px|Use the barrel lens attachment to the laser pointer to demonstrate refraction in the acrylic lens.]] | |||
<br clear='all'> | |||
*We use lenses to focus light to a point for experiments, or to make a wide parallel beam. | *We use lenses to focus light to a point for experiments, or to make a wide parallel beam. | ||
=== Polarizing Filters === | |||
<br clear='all'> | |||
[[Image:Polarizer.JPG|thumb|300px|]] | |||
'''Light waves can be random or polarized in one direction. ''' Polarized materials only allow light with a certain orientation to pass through. Have two students hold the nylon rope and generate a wave in the crossways direction. Place two straight back chairs back to back on either side of the rope so that it’s horizontal movement is limited. The waves will be dampened. Ask the students to generate a wave in the up and down direction. This will pass through between the chairs. This how a polarized light is blocked or passed through a polarizing filter. | |||
Use the polarizing filters to show that light from a laser or from an LCD monitor can be almost completely blocked as the filter is rotated. Two filters can be used to block non polarized light. | |||
<br clear='all'> | |||
[[Image:Polarizefork.JPG|thumb|300px|]] | |||
Clear materials such as plastics can change the polarity of light when they are under stress because their molecules get aligned in a certain way by forces. If you place a clear plastic spoon between two polarizing filters or between an LCD monitor (a polarized light source) and a polarizing filter you can see rainbow colored patches where light is being blocked or refracted in response to stresses in the material. | |||
*Liquid crystal displays have a polarized light source. The liquid crystal chemicals can be rearranged when electricity is applied to change the way they polarize light and thus let certain light pass through under the red, green and blue cells. This property can be used to control light in fiber networks and computers. | *Liquid crystal displays have a polarized light source. The liquid crystal chemicals can be rearranged when electricity is applied to change the way they polarize light and thus let certain light pass through under the red, green and blue cells. This property can be used to control light in fiber networks and computers. | ||
*CMDITR is | *CMDITR is creating new organic materials that can change their polarization in an electric field or when light of specific wavelength is provided. | ||
=== Lasers and diffraction grating === | |||
=== Links | <br clear='all'> | ||
[[Image:Laser_diffraction.jpg|thumb|300px|]] | |||
'''Lasers light is coherent and a precise wavelength.''' Place a diffraction grating in front of the laser pointer and shine it at a wall (never look into laser). There will be three dots, one for straight transmission and two diffracted dots on either side. Compare this to the pattern that appears from looking at a fluorescent bulb with a diffraction grating. | |||
*Researchers pick lasers that have precisely the wavelength they need for their experiments. For example most optical fiber communications operate at 850nm or 1300 nm wavelength. | |||
== Basic Light Poster == | |||
<embed_document width="100%" height="800">http://depts.washington.edu/cmditr/media/Basiclight_poster.pdf</embed_document> | |||
[http://depts.washington.edu/cmditr/media/Basiclight_poster.pptx Download PowerPoint file] | |||
== Links == | |||
[http://www.osa.org/educationresources/youtheducation/classroommaterials/default.aspx OSA classroom materials including the Optics Suitcase] | [http://www.osa.org/educationresources/youtheducation/classroommaterials/default.aspx OSA classroom materials including the Optics Suitcase] | ||
Line 66: | Line 175: | ||
[http://www.exploratorium.edu/snacks/index.html Exploratorium - Snacks are simple demo ideas - this is the premier organization for hands-on demos and learning] | [http://www.exploratorium.edu/snacks/index.html Exploratorium - Snacks are simple demo ideas - this is the premier organization for hands-on demos and learning] | ||
[http://www.osa.org/educationresources/youtheducation/classroommaterials/LightenUpWeb2.pdf Lighten Up - OSA and Girl Scouts] | |||
[http://www.pl.euhou.net/docupload/files/Excersises/WorldAroundUs/IndexOfRefraction/IndexOfRefraction.pdf Index of refraction lab] | |||
== Sources for Building your own kit == | |||
[http://depts.washington.edu/cmditr/media/optics.docx Cover art for Optics Kit] | |||
* [http://www.i-fiberoptics.com/laser-kits-projects-detail.php?id=2240 $51 Laser pointer education kit class II red laser pointer] | |||
* [http://scientificsonline.com/product.asp_Q_pn_E_3053471 Acrylic prisms set $34] | |||
* [http://scientificsonline.com/product.asp?pn=3081936 Mini Fluorescent tube Blacklight $18.95 ] | |||
* [http://www.dealextreme.com/p/12-led-uv-flashlight-black-1300 UV Flashlight- $5.00] | |||
* [http://www.arborsci.com/detail.aspx?ID=37 Large Color filter Product ID: 33-0190 pack $12] | |||
* [http://www.arborsci.com/detail.aspx?ID=894 Individual filter paddle samples $12] | |||
* [http://www.arborsci.com/detail.aspx?ID=1428 grow lens cubes (100s) $8 (clear gel to play with lens shapes)] | |||
* [http://www.arborsci.com/detail.aspx?ID=928 Glow paper $3.95] | |||
* [http://www.arborsci.com/detail.aspx?ID=395 slide mounted polarizing filters( 50) $33 ] | |||
* [http://www.arborsci.com/detail.aspx?ID=462 UV beads $5 ] | |||
* [http://www.officedepot.com/catalog/vendorRouter.do?configurableItemType=NORWOOD&id=976090 White flashlights 4 x $5] | |||
* [http://solar-center.stanford.edu/posters/ Nasa Spectroscopes $7] | |||
* [http://www.amazon.com/Green-Laser-Pointer-Astronomy-Military/dp/B0013HR77S/ref=sr_1_3?ie=UTF8&m=A3V6BK4D0HKA8F&s=electronics&qid=1271101852&sr=1-3 HDE green laser $11.05] | |||
* [http://www.glowhut.com/a6-size-electroluminescent-light-with-9v-invert69.html EL panel with power supply $29] | |||
* LED Flashlights with color filters |
Latest revision as of 11:02, 5 October 2011
Previous Topic | K-12 Outreach Kits and Labs | Next Topic |
Overview
The purpose of this kit is to introduce students about the basic properties of light such as color, straight beams, reflection, refraction and polarization. Each of these phenomena can be presented in a “discovery” mode in which students related their current knowledge by guessing what will happen. At a higher level some of the phenomena can be explained with formulas and confirmed with measurements. Following each demo description are ideas of how to tie the demo into the CMDITR science.
User Guide
Key Concepts and Demos
Diffraction Grating
White light is composed of many colors. Pass around the diffraction grating. Have them describe what they see. Are the colors the same for any light you look at? The diffraction grating is able to split white light into colors that make it up. (The diffraction grating works because of constructive and destructive interference, but this is higher level concept.) Students may be able to notice that the colors difference between an incandescent bulb, and LED and fluorescent bulb shown below. Connect this idea to other sources of rainbows colors such as a rainbow (reflection and dispersion within a drop of water), oil sheen on water (interference between nanolayers), or prisms (transmission and dispersion).
Additive Color Mixing
When red, green and blue are added together they produce white. Pass out the color flashlights. These produce red, green and blue light. What happens when two or more colors of light are combined?
- A RGB monitor has tiny red, green and blue dots. All colors including white can be made by mixing these three colors. CMDITR research with organic light emitting diodes has led to OLED displays which use thousands of red, green and blue lights to make all the points on the display.
Color filters
Light can be absorbed. Ask students what they know about color.
a. Pass out colored filter samples and have students look at the room. Which color filter makes the light of a certain color go away? Colored filters absorb different colors and let other colors through. The deluxe filter paddle also has a polarizing filter and a diffraction grating.
b. Ask which color paints are mixed together to make other colors. Is it possible to make white paint by mixing colored paints? (No this is because each color absorbs another part of the spectrum. If you added enough colors together eventually to would absorb all the light making black.) Have student pick three colors from the sample pack that when combined makes black or grey.If an organic solar cell appears red colored what does tell you about its absorption spectrum? The color of reflected light from a material represents the color of light that is not absorbed.
c. Print out the “red reveal” hidden message sheets. Ask students to find a filter that reveals the hidden message. The red filter will mask all the colors that are similar to red in the picture. This makes cyan, blue and purple layer that shows up as black because light from these is blocked by the red filter. Red and yellow on the design show up as white when viewed through the red filter. You can also learn how to make a red reveal message.
<embed_document width="55%" height="600">http://depts.washington.edu/cmditr/media/redreveal.pdf</embed_document> <embed_document width="55%" height="600">http://depts.washington.edu/cmditr/media/redreveal2.pdf</embed_document> <embed_document width="55%" height="600">http://depts.washington.edu/cmditr/media/colorwheel.pdf</embed_document>
- Reseach Connection Solar panels are black because they absorb many colors. We are trying to design new materials that can capture solar energy and convert the energy to electricity. We could make a blue solar cell. It would might pretty but it might not work as well as one that appears black. Why?
Spectroscope
The color of light can be described by wavelength. You may not notice it but every light has its own unique color. A spectroscope is an instrument that lets you measure all the colors present in a light source.
a. Point the spectroscope at a fluorescent light. Notice the green line that appears at the 5450 mark. Fluorescent bulbs are actually a little bit green. Some street lights are blue or even orange. This color depends on the chemistry of the materials used in the bulb.
b. Now place a color filter #89 that only transmits color in the green part of the spectrum. Notice that the red line disappears from the fluorescent spectrum. Try using other filters to isolated different lines. What rule can you come up with about what color filters do to the full color spectrum of light? ( A color filter blocks all colors except for the color it appears to be. Similarly reflective colors absorb all light except for the color they can be observed to reflect)
- LED s have distinct colors. Scientists and engineers are working to make LEDs that have light with the full spectrum of sunlight so colors look right. Other applications require LEDs with a very specific wavelength to match the material they must pass through such as plastic screens or fiber optics.
- We use instruments like the spectroscope to measure the light absorbed by chemicals we produce and to measure the light the color produce when they stimulated with lasers and electricity.
UV sensitive beads
Some portions of the electromagnetic spectrum is invisible. Point out the colors on the electromagnetic spectrum chart and show that some types of radiation are not visible. Pass out some UV beads. These are photochromic beads which change color in the presence of UV light but revert to white in the dark. Ask students if all light is visible. Have them place the beads in various places around the classroom under lights, in the dark and in the sun. Explain that UV light is invisible but very powerful and is the cause of sun burns.
- UV light is damaging to the body. It is also damaging to organic chemicals that we use in our solar cells. One of the challenges is to make design chemicals that do not break down in the presence of UV light.
Glow Paper
Some materials absorb light and then continue to emit it over time. Some colors of light do not have enough energy to excite these substances. Turn off the lights in the room. Use the three colored flashlights, the white flashlight, daylight and the red laser to stimulate the glow-in-the dark paper. The red light should not be able to make it glow even though the laser pointer is very intense. This is because the chemical in the paper requires a minimum energy of light in order to excite its electrons to a higher energy level. Once the higher level is reached the energy slowly decays back to the ground state emitting light that is observed as glowing.
- In photonics research we carefully match the color of light we are using excite a test substance with the chemical properties of the sample.
Quantum Dots Solutions
Materials can be made that designed that absorb and emit radiation at specific wavelengths. These vials contain extremely small 2-5nm particles of cadmium selenium that have been grown to specific sizes because of their light absorbing qualities. These particles exhibit fluorescence; they absorb light at one color and emit light at a different wavelength. In the visible spectrum they absorb and emit yellow and pale red. They absorb ultraviolet and fluoresce in green, red and orange.
a. Examine the vials in regular light. Predict what color the vials will appear under UV light.
b. Expose the vials to UV light and discuss why this is different.
- Research Connection: It is possible us quantum dots as a light antenna to absorb light and pass energy to another chemical. Some quantum dots for example could be used to trap infrared (IR ) light which would help solar cells work on cloudy days when IR passes through the clouds but visible light is mostly blocked.
Electroluminescent Panel
Electricity can be used to excite a material and make it emit light. Electroluminescent panels have a transparent conductor layer, a layer of phosphor and a metal back electrode. When the front and back electrode are energized with a high frequency current the phosphor in between is stimulated and emits light.
- Research Connection: Electroluminescent panels are similar to the structure of Organic Light Emitting Diodes (OLEDs). Instead of a layer of phosphor the OLED contains an organic chemical that emits light after being excited with electricity. The organic chemicals can be tuned to get specific colors. OLEDs are now used for flat displays and televisions.
Laser pointer
Light goes in a straight line until it interacts with matter. All light sources produce beams of light. Lighting usually produces many beams going many directions. a. A laser produces a very bright, focused beam. Use the laser show the path of a light beam. Laser light is used to guide rockets, in surveying or carpentry to line things up, or even to guide farm machinery. Place the laser along a flat surface such as the floor or table and show that it is not affected by gravity.
b. Fill the plastic tub with water and add some powdered milk powder to make the light beam visible. A tub of clear gelatin can also be used for this demonstration.
Mirrors and lasers
Light can be reflected. First ask what kinds of objects reflect light. Test the theories about what will reflect by pointing the laser at the objects that are suggested. They should be able to describe the quality of shiny, glassy or metallic being needed for mirrors. Place a mirror on the block which is attached to a protractor. Place the cylinder lens end tip on the laser so that it produces flat line instead of a dot. Orient the line so it is vertical (with the cylindrical lens horizontal). This will make it easier to see the light ray and its reflection on the table. Use the protractor to measure the angle of light coming in (angle of incidence) and the angle of reflection. What is the rule for this? (the angle of incidence equals the angle of reflection) Challenge: what arrangement of mirrors would be needed to reflect a laser beam into a complete circle? Optical fiber has smooth surfaces and narrow diameter. Light reflects inside the tube until it emerges from the end. This is called total internal reflection.
- a. We do many experiments with lasers that pass through many lenses, filters and sensors on a special optics table. We move the laser beam around the table using mirrors and large optical fibers. Some lasers are so powerful they can burn a hole in wood if the beam is absorbed. Mirrors can reflect this light without getting hot at all.
Refraction with grow cubes and prisms
Light can be refracted. One day before the demonstration place several of the optic grow cubes into water in a plastic bag. Each cube will expand into a 3 cm, optically clear cube. Use the single edge razor to cut the cube into various shapes used in optics. Alternatively cast a sheet of clear gelatin using three times as much gelatin as is called for on the recipe. Use the laser pointer to show how lenses and prisms work. Try making a convex lens, a concave lens, an equilateral prism, a fiber optic tube, a periscope with right angle prisms.
Use the acrylic prism set to demonstrate various optics phenomena. If possible use two lasers to show parallel beams.
- We use lenses to focus light to a point for experiments, or to make a wide parallel beam.
Polarizing Filters
Light waves can be random or polarized in one direction. Polarized materials only allow light with a certain orientation to pass through. Have two students hold the nylon rope and generate a wave in the crossways direction. Place two straight back chairs back to back on either side of the rope so that it’s horizontal movement is limited. The waves will be dampened. Ask the students to generate a wave in the up and down direction. This will pass through between the chairs. This how a polarized light is blocked or passed through a polarizing filter.
Use the polarizing filters to show that light from a laser or from an LCD monitor can be almost completely blocked as the filter is rotated. Two filters can be used to block non polarized light.
Clear materials such as plastics can change the polarity of light when they are under stress because their molecules get aligned in a certain way by forces. If you place a clear plastic spoon between two polarizing filters or between an LCD monitor (a polarized light source) and a polarizing filter you can see rainbow colored patches where light is being blocked or refracted in response to stresses in the material.
- Liquid crystal displays have a polarized light source. The liquid crystal chemicals can be rearranged when electricity is applied to change the way they polarize light and thus let certain light pass through under the red, green and blue cells. This property can be used to control light in fiber networks and computers.
- CMDITR is creating new organic materials that can change their polarization in an electric field or when light of specific wavelength is provided.
Lasers and diffraction grating
Lasers light is coherent and a precise wavelength. Place a diffraction grating in front of the laser pointer and shine it at a wall (never look into laser). There will be three dots, one for straight transmission and two diffracted dots on either side. Compare this to the pattern that appears from looking at a fluorescent bulb with a diffraction grating.
- Researchers pick lasers that have precisely the wavelength they need for their experiments. For example most optical fiber communications operate at 850nm or 1300 nm wavelength.
Basic Light Poster
<embed_document width="100%" height="800">http://depts.washington.edu/cmditr/media/Basiclight_poster.pdf</embed_document>
Links
OSA classroom materials including the Optics Suitcase
Innovative Methods to Teach Optics in the Grade 5- (including jello optics)
Hands On Optics from OSA, SPIE and NOAO
Lighten Up - OSA and Girl Scouts
Sources for Building your own kit
- $51 Laser pointer education kit class II red laser pointer
- Acrylic prisms set $34
- Mini Fluorescent tube Blacklight $18.95
- UV Flashlight- $5.00
- Large Color filter Product ID: 33-0190 pack $12
- Individual filter paddle samples $12
- grow lens cubes (100s) $8 (clear gel to play with lens shapes)
- Glow paper $3.95
- slide mounted polarizing filters( 50) $33
- UV beads $5
- White flashlights 4 x $5
- Nasa Spectroscopes $7
- HDE green laser $11.05
- EL panel with power supply $29
- LED Flashlights with color filters