Optical behavior - SENS

Optical behavior - SENS

Optical behavior Topic 10 Reading assignment Askeland and Phule, The Science and Engineering of Materials, 4th Ed. ,Ch. 20.

Shackelford, Materials Science for Engineers, 6th Ed., Ch. 16. Chung, Composite Materials, Ch. 8. The Electromagnetic Spectrum Light is energy, or radiation, in the form of waves or particles called photons that can be

emitted from a material. The important characteristics of the photons their energy E, wavelength , and frequency are related by the equation Figure 20.1 The electromagnetic spectrum of radiation; the bandgaps and cutoff frequencies for some optical materials are also shown.

(Source: From Optoelectronics: An Introduction to Materials and Devices, by J. Singh. Copyright 1996 The McGraw-Hill Companies. Reprinted by permission of The McGraw-Hill Companies.) Refraction of light as it passes from vacuum (or air) into a

transparent material. High index Low index Refractive index n

n = Speed of light in vacuum (essentially the same as that in air), divided by the speed of light in a transparent material. n1 sin 1 = n2 sin 2

Snells Law If n1 > n2, then 2 > 1 Since a larger refractive index means lower speed, n1 > n2 means v2 > v1. Thus, the medium with the larger speed is associated with a larger angle

between the ray in it and the normal. Dispersion Frequency dependence of the index of refraction Reflection of light at the surface of

an opaque metal occurs without refraction. Reflectance (reflectivity) R R = Fraction of light reflected Fresnels formula R = [(n-1)/(n+1)]2 Strictly valid for = 0 (normal incidence)

i High n results in high R (i.e., R approaches 1) Reflection of light at the surface of a

transparent material occurs along with refraction. When 2 = 90, the refracted ray is along the interface

n2 sin 1 . n1 The value of 1 corresponding to 2 = 90 is called c (the critical angle).

When 1 > c, there is no refracted ray and all the incident ray is reflected. Total internal reflection when 1 exceeds c Cable with 144 glass fibers (right)

Copper-wire cable (left) Applications of optical fiber Communication Digital processing Sensing (extrinsic

smartness) Optical fiber An optical fiber guides the light in it so that the light stays inside even when the fiber is bent.

Optical fiber This is because the fiber has a cladding of refractive index n2 and a core of refractive index n1, such that n1 > n2 and total internal reflection takes place when 1 > c. This means that the incident ray should have an angle of incidence more than c in order to

have the light not leak out of the core. Hence, incoming rays that are at too large an angle (exceeding NA) from the axis of the fiber leak. The coaxial design of commercial optical fibers Core diameter: 5-100 microns

Core material High-purity silica glass Attenuation of light Power loss through a 16-kilometer (19mile) thickness of optical fiber glass is equivalent to the power loss through a

25-millimeter (1-inch) thickness of ordinary window glass. Light scattering is the result of local refraction at interfaces of

second-phase particles or pores. The case for scattering by a pore is illustrated here. Specular reflection occurs relative to

the average surface, and diffuse reflection occurs relative to locally nonparallel surface elements. 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.3 (a) When a ray of light enters from material 1

into material 2, if the refractive index of material 1 (n1) is greater than that of material 2 (n2), then the ray bends away from the normal and toward the boundary surface. [1, 9] (b) Diagram a light beam in glass fiber for Example 20.1. The acceptance angle of the fiber is defined as twice NA. Rays within the

acceptance angle do not leak. The numerical aperture (NA) of the fiber is defined as n1 sin NA. Since NA = 90 - c, n1 sin NA = n1 sin (90 - c) = n1 cos c

n2 sin c . n1 n2 cos c 1 n1

n 2 1

2 2 1 n n

2 n1 n

n1 2 2 2 2

Numerical n2 n2 aperture n 1 2 1

= n1 2 1

n n 2

2 An optical fiber (or optical wave guide) has a low-index glass cladding and a normal-index glass core. The refractive index may decrease sharply or gradually from core to cladding, depending on

how the fiber is made. A sharp decrease in index is obtained in a composite glass fiber; a gradual decrease is obtained in a glass fiber that is doped at the surface to lower the index. A gradual decrease is akin to having a diffuse interface between core and cladding. As a

consequence, a ray does not change direction sharply as it is reflected by the interface A sharp decrease in index corresponds to a sharp interface and a ray changes direction sharply upon reflection by the interface.

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Step-index fiber Graded-index fiber

Path of rays entering at different angles A fiber with a sharp change in index is called a stepped index fiber. A fiber with a gradual change in index is called a graded index fiber.

A graded index fiber gives a sharper output pulse (i.e., less pulse distortion) in response to an input pulse, compared to a stepped index fiber. An optical fiber may have different diameters of the core.

A small core (e.g., 3 m diameter) means that only rays that are essentially parallel to the fiber axis can go all the way through the fiber, as offaxis rays need to be reflected too many times as they travel through the fiber and, as a result, tend to leak. A large core (e.g., 50-200 m) means that both on-axis and off-axis rays make their way through

the fiber. A fiber with a large core is called a multimode fiber, whereas one with a small core is called single-mode fiber. A single-mode fiber gives less pulse distortion than a multimode fiber, so it

is preferred for long-distance optical communication. However, the intensity of light that can go through a singlemode fiber is smaller than that for a multimode fiber. The NA tends to be around 0.1 for a single-mode glass fiber and around 0.2 for a multimode glass fiber.

A single-mode fiber tends to have the cladding thicker than the core, so that the overall fiber diameter is not too small. For example, the cladding may be 70-150 m thick, while the core diameter is 3 m. A multimode fiber tends to have the

cladding thinner than the core, as the core is already large. For example, the cladding may be 1-50 m thick, while the core diameter is 50-200 m. A single-mode fiber is stepped index, whereas a multimode fiber may be either stepped index or graded index.

3 types of optical fiber Single-mode stepped index Multimode stepped index Multimode graded index Pulse distortion increases in the order: single-mode stepped index, multimode

graded index and multimode stepped index. Step-index fiber Graded-index fiber Single-mode fiber

Design of a Fiber Optic System Optical fibers are commonly made from high-purity silicate glasses. They consist of a core that has refractive index (~ 1.48) that is higher than a region called cladding (refractive index ~ 1.46). This is why even a simple glass fiber in air (refractive index 1.0) can serve as an optical fiber. In designing a fiber optic transmission

system, we plan to introduce a beam of photons from a laser into a glass fiber whose index of refraction of is 1.5. Design a system to introduce the beam with a minimum of leakage of the beam from the fiber. Figure 20.3 (b) Diagram a light beam in glass fiber

for Example 20.1. Example 20.1 SOLUTION To prevent leakage of the beam, we need the total internal reflection and thus the angle t must be at least 90o. Suppose that the photons enter at a 60o angle to the axis of the fiber. From Figure 20.3(b), we find that i = 90 - 60

= 30o. If we let the glass be Material 1 and if the glass fiber is in air (n = 1.0), then Because t is less than 90o, photons escape from the fiber. To prevent transmission, we must introduce the photons at a shallower angle, giving t = 90o.

Example 20.1 SOLUTION (Continued) If the angle between the beam and the axis of the fiber is 90 - 41.8 = 48.2 or less, the beam is reflected. If the fiber were immersed in water (n = 1.333), then: In water, the photons would have to be introduced at an angle of less than 90 62.7 = 27.3 in order to prevent

transmission. Light is absorbed as it travels through any medium (whether solid, liquid or gas), such that the intensity I at distance x is related to the intensity Io at x = 0 by Beer-Lambert law

I = Io e-x where is the absorption coefficient, which varies from one medium to another and has the unit m-1. The greater is , the more severe is the absorption. The intensity decreases exponentially as

light travels through the medium. 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.2 (a) Interaction of photons with a material. In addition to reflection, absorption, and transmission, the bream changes direction, or is refracted. The change in direction is

given by the index of refraction n. (b) The absorption index (k) as a function of wavelength. I ln x Io Converting natural logarithm to

logarithm to the base 10 gives I 2.3 log x Io

Attenuation loss (in dB) = I 10 log . Io When I/Io = 0.1, the attenuation loss is 10 dB.

When I/Io = 0.01, the attenuation loss is 20 dB. Attenuation loss (in dB) = 10x 2.3

Hence, the attenuation loss is proportional to x. A typical loss for glass fibers is around 1 dB/km. Polymers are not as attractive as glass for use as optical fibers because of their relatively high attenuation loss.

The imperfect coupling between the light source and an optical fiber is another source of loss, called coupling loss, which is typically 10-12 dB. This loss is because the light from the source has rays that are at angles greater than the acceptance angle of the

optical fiber. Even if the light source (a light emitting diode with rays exiting it within an angle of 100) is butt directly with the optical fiber, coupling loss still occurs. Less coupling loss occurs if the light source is a laser, since laser light diverges negligibly as it travels.

The intensity of light (related to the amplitude) that goes through an optical fiber is called the light throughput, which decreases as the fiber decreases in diameter, as the fiber bends (causing leakage through the cladding) and as the fiber is damaged.

An optical fiber may contain partially reflecting (partially transmitting) mirrors at certain points along its length within the fiber. In this way, a part of the light is reflected and a part is transmitted. By measuring the time it takes for the reflected light to reach the start of the fiber,

information can be obtained concerning the location of the strain or damage. This technique is called time domain reflectometry. 3 types of optical fiber sensor Transmission-gap sensor Evanescent-wave sensor

Internal-sensing sensor Transmission-gap sensor A transmission-gap sensor has a gap between the input fiber and the output fiber (which are end to end except for the gap) and the disturbance at the gap affects the output. The disturbance may be

pressure, temperature, etc. In case that the ends of the fibers delineating the gap are polished to enhance light reflection, a slight change in the gap distance causes a change in phase difference between the light rays reflected from the adjacent ends of the two fibers and travelling in the same direction back toward the light source.

Evanescent-wave sensor An evanescent-wave sensor has a part of the length of an optical fiber stripped of its cladding. The stripped part is the sensor, since the light loss from the stripped part is affected by the refractive index of the

medium around the stripped part. Hence, a change in medium is detected by this sensor. Internal-sensing sensor An internal-sensing sensor is just an unmodified optical fiber; the

amplitude and phase of light going through the fiber is affected by the disturbance encountered by the fiber. 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license.

Figure 20.8 Elements of a photonic system for transmitting information involves a laser or LED to generate photons from an electrical signal, optical fibers to transmit the beam of photons efficiently, and an LED receiver to convert the photons back into an electrical signal. Example 20.3

Determining Critical Energy Gaps Determine the critical energy gaps that provide complete transmission and complete absorption of photons in the visible spectrum. Example 20.3 SOLUTION The visible light spectrum varies from 4 10-5 cm to 7 10-5 cm. The minimum Eg required to assure that no photons in the

visible spectrum are absorbed is: Example 20.3 SOLUTION (Continued) The maximum Eg below which all of the photons in the visible spectrum are absorbed is: For materials with an intermediate Eg, a portion of the

photons in the visible spectrum will be absorbed. Photoconduction (For light detection) Photoresponse Ratio of the light conductivity

to dark conductivity Describes the effectiveness of a light detector Luminescence Photon absorption is accompanied by the reemission of some photons of visible light.

May be accompanied by the absorption of other forms of energy (thermal, mechanical and chemical) or particles (e.g., high-energy electrons). Any emission of light from a substance for any reason other than a rise in its temperature.

Luminescence Atoms of a material emit photons of electromagnetic energy when they return to the ground state after having been in an excited state due to the absorption of energy.

Luminescence 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.14 Luminescence occurs

when photons have a wavelength in the visible spectrum. (a) In metals, there is no energy gap, so luminescence does not occur.

(b) Fluorescence occurs when there is an energy gap. (c) Phosphorescence occurs when the photons are emitted over a period of time

due to donor traps in the energy gap. Luminescence - Conversion of radiation to visible light. Fluorescence - Emission of light obtained typically within ~ 10-8

seconds. Phosphorescence - Emission of radiation from a material after the stimulus is removed. X-ray fluoresence

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.11 Characteristic x-rays are produced when electrons change from one energy level to a lower energy level, as illustrated here for copper. The energy and wavelength of the x-rays are fixed by the energy differences between the energy levels.

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.4 The linear absorption coefficient relative to wavelength for several metals. Note the sudden decrease in the absorption coefficient for wavelengths greater than the absorption edge.

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.24 Intensity of the initial spectrum from a copper x-ray source before filtering (for Problem 20.43). 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used

herein under license. Figure 20.10 The continuous and characteristic spectra of radiation emitted from a material. Low-energy stimuli produce a continuous spectrum of low-energy, long-wavelength photons. A more intense, higher energy spectrum is emitted when the stimulus is more powerful until, eventually, characteristic radiation is observed.

X-ray fluorescence for elemental analysis 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.22 Results from an x-ray fluorescence analysis of an unknown metal sample (for Problem 20.41).

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.6 Relationships between absorption and

the energy gap: (a) metals, (b) Dielectrics and intrinsic semiconductors, and (c) extrinsic semiconductors.

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.5 Fractions of the original beam that are reflected, absorbed, and transmitted. 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license.

Figure 20.2 (a) Interaction of photons with a material. In addition to reflection, absorption, and transmission, the bream changes direction, or is refracted. The change in direction is given by the index of refraction n. (b) The absorption index (k) as a function of wavelength.

Absorption curve for a silicate glass containing about 1% cobalt oxide. The characteristic blue color of this material is due to the absorption of much of the red end of the visible-light spectrum.

Electroluminescence Use of an applied electrical signal to stimulate photons from a material. Light-emitting diode

(LED) pn-junction under forward bias 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.15 Diagram of a light-emitting diode (LED). A

forward-bias voltage across the p-n junction produces photons. A light-emitting diode Surface-emitting LED Edge-emitting LED

Photonic bandgap materials These are structures produced using micromachined silicon or colloidal particles, such that there is a range of frequencies that cannot be transmitted

through the structure. Solar cell Short-circuited pn-junction Laser

The acronym stands for light amplification by stimulated emission of radiation. A beam of monochromatic coherent radiation produced by the controlled emission of photons.

Characteristics of a laser beam Parallel (not diverging) Nearly monochromatic Coherent Nearly monochromatic

Of nearly one wavelength Frequency bandwidth (range of frequencies) is narrow. He-Ne laser: bandwidth 104 Hz Gas discharge tubes: bandwidth 109 Hz White light: bandwidth 3 X 1014 Hz

Coherence Any two points in the laser beam having a predictable phase relationship Condition for coherence t << 1

x = ct x << c/ = coherence length Stimulation He-Ne laser

Semiconductor laser Fermi Without bias 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license.

Figure 20.17 Creation of a laser beam from a semiconductor: (a) Electrons are excited into the conduction band by an applied voltage. (b) Electron 1 recombines with a hole to produce a photon. The photon stimulates the emission of photon 2 by a second recombination. (c) Photons reflected from the mirrored end stimulate even more photons. (d) A fraction of the photons are emitted as a laser beam, while the rest are reflected to simulate more

recombinations. 2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Figure 20.18 Schematic cross-section of a GaAs laser. Because the surrounding p- and n-type GaAlAs layers have a higher energy gap and a lower index of refraction than

GaAs, the photons are trapped in the active GaAs layer. Solid-state lasers Ruby laser (single crystal Al2O3 doped with a small amount of Cr2O3) emits at 6943 Yttrium aluminium garnet (Y3Al5O12

YAG) doped with neodymium (Nd) emits at 1.06 m Ruby laser Figure 20.16 The laser converts a stimulus into a beam of coherent photons. The mirror on one side is 100%

reflecting, the mirror on the right transmits partially. (Source: From Optical Materials: An Introduction to Selection and Application, by S. Musikant, p. 201, Fig. 10-1. Copyright 1985 Marcel Dekker, Inc.) Electrons of a Cr3+ ion

Ruby laser Ruby laser Thermal emission Emission of photons from a

material due to excitation of the material by heat. Figure 20.19 Intensity in relation to wavelengths of photons emitted

thermally from a material. As the temperature increases, more photons are emitted from the visible spectrum.

2003 Brooks/Cole, a division of Thomson Learning, Inc. Thomson Learning is a trademark used herein under license. Unique structural configuration of liquid crystal polymers Use of a one-quarter-wavelength thick coating minimizes surface reflectivity. The coating has an intermediate index of refraction, and the primary reflected wave

is just cancelled by the secondary reflected wave of equal magnitude and opposite phase. Such coatings are commonly used on microscope lenses.

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