Difference between revisions of "Light lab Pchem"
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==Examples== | ==Examples== | ||
+ | [[Reduction_of_UV_light_intensity_using_Anti_Fog_Goggles|Reduction of UV light intensity using Anti Fog Goggles]] | ||
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+ | [[Iphone_Flashlight|Light Emission of Iphone Flashlight]] | ||
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+ | [[Reflection_of_Tungsten_Bulb|Reflection of Tungsten Bulb Off of Different Metals]] | ||
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[[Stained_Glass|Transmission of Light Through Stained Glass]] | [[Stained_Glass|Transmission of Light Through Stained Glass]] | ||
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+ | [[Red_Versus_Green_Lasers|Red vs Green Lasers Through Filter]] | ||
[[Sunglasses_UV|Sunglasses blocking UV light]] | [[Sunglasses_UV|Sunglasses blocking UV light]] |
Latest revision as of 20:59, 31 January 2019
Welcome to the Light lab.
In the introductory chapter we were exposed to a series of experiments that were not appropriately described by the current theory, ie. classical mechanics. These experiments lead to the development of quantum mechanics. Many of these experiments involved "light." In this lab activity we will explore light at a deeper level.
Introduction
- Review of emission spectra using the photodiode array detector, including Rydberg equation.
Examples
Reduction of UV light intensity using Anti Fog Goggles
Light Emission of Iphone Flashlight
Reflection of Tungsten Bulb Off of Different Metals
Transmission of Light Through Stained Glass
Red vs Green Lasers Through Filter
Emission Spectra of Different Metals
Submerge Christmas light in liquid nitrogen
Emission intensity of mercury lamp
The Transmission of UV Light through Polarized Film
Comparison of iPhone cameras across multiple generations