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ISSUES TO ADDRESS... What happens when light shines on a material ? 1 Why do materials have characteristic colors? Optical applications: --luminescence.

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Presentation on theme: "ISSUES TO ADDRESS... What happens when light shines on a material ? 1 Why do materials have characteristic colors? Optical applications: --luminescence."— Presentation transcript:

1 ISSUES TO ADDRESS... What happens when light shines on a material ? 1 Why do materials have characteristic colors? Optical applications: --luminescence --photoconductivity --solar cell --optical communications fibers Why are some materials transparent and other not? CHAPTER 19: OPTICAL PROPERTIES

2 2 Incident light is either reflected, absorbed, or transmitted: Optical classification of materials: Adapted from Fig. 21.10, Callister 6e. (Fig. 21.10 is by J. Telford, with specimen preparation by P.A. Lessing.) LIGHT INTERACTION WITH SOLIDS

3 3 Absorption of photons by electron transition: Metals have a fine succession of energy states. Near-surface electrons absorb visible light. Adapted from Fig. 21.4(a), Callister 6e. OPTICAL PROPERTIES OF METALS: ABSORPTION

4 4 Electron transition emits a photon. Reflectivity = I R /I o is between 0.90 and 0.95. Reflected light is same frequency as incident. Metals appear reflective (shiny)! Adapted from Fig. 21.4(b), Callister 6e. OPTICAL PROPERTIES OF METALS: REFLECTION re-emitted photon from material surface

5 5 Absorption by electron transition occurs if h > E gap If E gap < 1.8eV, full absorption; color is black (Si, GaAs) If E gap > 3.1eV, no absorption; colorless (diamond) If E gap in between, partial absorption; material has a color. Adapted from Fig. 21.5(a), Callister 6e. SELECTED ABSORPTION: NONMETALS incident photon energy h

6 6 Color determined by sum of frequencies of --transmitted light, --re-emitted light from electron transitions. Ex: Cadmium Sulfide (CdS) -- E gap = 2.4eV, -- absorbs higher energy visible light (blue, violet), -- Red/yellow/orange is transmitted and gives it color. Ex: Ruby = Sapphire (Al 2 O 3 ) + (0.5 to 2) at% Cr 2 O 3 -- Sapphire is colorless (i.e., E gap > 3.1eV) -- adding Cr 2 O 3 : alters the band gap blue light is absorbed yellow/green is absorbed red is transmitted Result: Ruby is deep red in color. Adapted from Fig. 21.9, Callister 6e. (Fig. 21.9 adapted from "The Optical Properties of Materials" by A. Javan, Scientific American, 1967.) COLOR OF NONMETALS

7 7 Transmitted light distorts electron clouds. Result 1: Light is slower in a material vs vacuum. Index of refraction (n) = speed of light in a vacuum speed of light in a material Material Lead glass Silica glass Soda-lime glass Quartz Plexiglas Polypropylene n 2.1 1.46 1.51 1.55 1.49 --Adding large, heavy ions (e.g., lead can decrease the speed of light. --Light can be "bent" Result 2: Intensity of transmitted light decreases with distance traveled (thick pieces less transparent!) Selected values from Table 21.1, Callister 6e. TRANSMITTED LIGHT: REFRACTION

8 8 Process: Ex: fluorescent lamps Adapted from Fig. 21.5(a), Callister 6e. APPLICATION: LUMINESCENCE incident radiation emitted light

9 9 Description: Ex: Photodetector (Cadmium sulfide) APPLICATION: PHOTOCONDUCTIVITY

10 10 p-n junction: Operation: --incident photon produces hole-elec. pair. --typically 0.5V potential. --current increases w/light intensity. Solar powered weather station: polycrystalline Si Los Alamos High School weather station (photo courtesy P.M. Anderson) APPLICATION: SOLAR CELL

11 11 Design with stepped index of refraction (n): Design with parabolic index of refraction Parabolic = less broadening = improvement! Adapted from Fig. 21.19, Callister 6e. (Fig. 21.19 adapted from S.R. Nagel, IEEE Communications Magazine, Vol. 25, No. 4, p. 34, 1987.) Adapted from Fig. 21.20, Callister 6e. (Fig. 21.19 adapted from S.R. Nagel, IEEE Communications Magazine, Vol. 25, No. 4, p. 34, 1987.) APPLICATION: FIBER OPTICS

12 12 When light (radiation) shines on a material, it may be: --reflected, absorbed and/or transmitted. Optical classification: --transparent, translucent, opaque Metals: --fine succession of energy states causes absorption and reflection. Non-Metals: --may have full (E gap 3.1eV), or partial absorption (1.8eV < E gap = 3.1eV). --color is determined by light wavelengths that are transmitted or re-emitted from electron transitions. --color may be changed by adding impurities which change the band gap magnitude (e.g., Ruby) Refraction: --speed of transmitted light varies among materials. SUMMARY

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