Optoelectronic Devices EE 2200 Lecture PDF
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Missouri S&T
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These lecture notes provide an overview of optoelectronic devices. It includes a discussion of related technologies like photonics and electronics, and details various types of devices. The document also covers application examples like fiber optic communications and optical sensing, along with other definitions, such as photon, light, and the electromagnetic spectrum.
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OPTOELECRONIC DEVICES Optoelectronic Devices - the electronic technology in which optical radiation is emitted, modified, or converted (as in electrical-to-optical or optical-to- electrical). Related technologies: Photonics - science and technolo...
OPTOELECRONIC DEVICES Optoelectronic Devices - the electronic technology in which optical radiation is emitted, modified, or converted (as in electrical-to-optical or optical-to- electrical). Related technologies: Photonics - science and technology concerned with the behavior of photons Electronics - science and technology concerned with the behavior of electrons Types of devices that are based on semiconductor junction electronics include: Photodiodes (PDs) – optical radiation is converted to an electrical signal Light-Emitting Diodes (LEDs) – electrical energy is converted to an optical signal Laser Diodes (LDs) – electrical energy is converted to optical energy in laser form Application Examples: Fiber optic communications Image processing Optical sensing Other Definitions: Photon - a quantum of electromagnetic energy with no mass, no charge, and energy hc/λ. Light - electromagnetic radiation in the ultraviolet, visible, and infrared bands or optical range Electromagnetic (EM) Spectrum - radiation of all frequencies or wavelengths including electrical power transmission, radio frequencies, optical frequencies, and high-energy rays. Wavelength λ (in vacuum) or frequency f are related by λ f = c where c is the speed of light in vacuum. Radiation - energy emitted or propagated as waves and energy quanta. Radiometry – the measurement of radiant EM energy at specific wavelength ranges. © Watkins 2009 MISSOURI S&T Page 18 of 30 ELECTROMAGNETIC ENERGY The propagation of electromagnetic energy may be characterized by the vacuum wavelength λ, frequency f = ω/2π, or quantum energy Ep. These waves travel with a phase velocity of vP. Material influences can be described by the index of refraction or refractive index n for light propagation. The wavelength and frequency are related as λ f = c where c is the speed of light in vacuum. The quantum energy is Ep = hf = hc/λ where h is Planck’s constant. The phase velcity is vp = c/n where n is the refractive index (n is unitless and is equal to or greater than 1). Divisions of the electromagnetic spectrum include the following. Radio Frequency (RF) - electromagnetic radiation band with frequencies between about 10 kHz and 300,000 Mhz. Shortwave Spectrum - EM band with wavelengths between about 200 meters and 20 meters; includes the middle bands of radio frequencies. Microwave Spectrum - EM band with wavelengths between about 1 meters and 1 millimeters; includes the upper bands of radio frequencies. Light - electromagnetic radiation in the ultraviolet, visible, and infrared bands or optical range with wavelengths between about 1 nm and 105 nm. X-rays - electromagnetic radiation with wavelengths between about 10 nm and 0.01 nm; usually described as high-energy photons. © Watkins 2009 MISSOURI S&T Page 19 of 30 OPTICS: THE NATURE OF LIGHT Light refers to radiation in the ultraviolet, visible, and infrared portions of the electromagnetic spectrum. The wavelength λ is associated with color in the visible portion of the spectrum. The effective wavelength inside a material, as well as the phase velocity of light, is then decreased by the refractive index. The effective wavelength and phase velocity are then λ /n and c / n. Preferred designation for wavelength: vacuum wavelength rather than frequency f or energy. Preferred designation for semiconductor applications: photon energy EP Optical Spectrum: Optical wavelengths extend beyond what the eye can detect and include wavelengths between about 1 nm and 105 nm which interact with materials in similar ways. For instance, the physical mechanisms behind many optical sources are electronic and molecular transition and the methods of beam control often depend on reflection and refraction from interfaces. Light is subdivided into the ultraviolet, visible, and infrared bands. There are not precise wavelength divisions between bands. Light Bands Lower Wavelength Limit Upper Wavelength Limit Infrared (IR) about 700 nm about 105 nm Visible about 450 nm about 700 nm Ultraviolet (UV) about 1 nm about 450 nm Ultraviolet Visible Infrared λ f Optical Spectrum © Watkins 2009 MISSOURI S&T Page 20 of 30 LIGHT ANALYSIS Wave-Photon Duality: Light is unusual in that it readily displays both wave-like and quantum behavior. Many of the properties of light can be adequately described by waves. Notable exceptions include some cases of emission and absorption. In particular, photoelectric emission led to the concept of photons which was part of the development of the quantum mechanics. Also, the operation of laser diodes and photodiodes can only be explained using a quantum description of semiconductor and light. The quantum energy Ep = hf = hc/ λ where h is Planck’s constant A comparison of the parameters and representations are given. Wavelengths Frequency Quantum Energy 105 nm 2.998 x 1012 Hz 1.240 x 10-02 eV 700 nm 4.283 x 1014 Hz 1.771 eV 450 nm 6.662 x 1014 Hz 2.755 eV 1 nm 2.998 x 1017 Hz 1.240 x 103 eV Analysis of Optical Phenomena Ray Optics - a geometric representation of the behavior of light (also called geometrical optics) which corresponds to the limiting case of λ → 0. Electromagnetic (EM) Optics - or physical optics, an electromagnetic representation of the behavior of light using Maxwell’s equations (limiting case as photon number approaches ∞). Quantum Optics - the most general representation of the behavior of light in terms of photons, i.e. radiant energy packets, using quantum mechanics. Interaction with Semiconductors Absorption - loss due to energy conversion as light passes through a material. Photon can be absorbed by electron causing an upward band- to-band transition. Emission - conversion of energy into light. Photons can be emitted as electrons undergo a downward band-to-band transition. © Watkins 2009 MISSOURI S&T Page 21 of 30 SEMICONDUCTOR OPTICAL DEVICES Photodetectors: Semiconductor structures - Incident photons are converted by semiconductor structures into usable electrons. Solar cells convert light to electrical power. Common devices for imaging and information detection are CCDs (charge coupled devices), photodiodes, and avalanche photodiodes. The design of semiconductor photodetectors depends on the wavelength sensitivity of the materials. For instance, silicon and germanium are sensitive across the visible spectrum and near infrared spectrum. The compound semiconductors InGaAsP and GaAs are sensitive in the upper visible and near infrared. The peak quantum efficiency (electronic conductors generated per incident photon) of about 900 nm in silicon is near its upper cut-off wavelength of 1100 nm. Detectors made of materials such as InGaAsP are optimized for important optical fiber wavelengths of 1300 nm and 1550 nm. Ultraviolet Visible Near Infrared Si Ge InGaAsP GaAs Light Sensitivity of Common Semiconductors Semiconductor Sources: Light Emitting Diodes and Laser Diodes - Light is emitted due to quantum transitions in gases, liquids, or solids. Injection electrolumninescence is the mechanism for light emission in semiconductor diodes. Carriers make a downward transition from the conduction band to the valence band and emit light. Laser sources are characterized by high coherence and directionality over an extremely narrow spectrum. © Watkins 2009 MISSOURI S&T Page 22 of 30 LIGHT ABSORPTION Attenuation: A media in which light is propagating may be lossy. For a given wavelength, the irradiance will decrease at a rate proportional to the irradiance magnitude. The resulting loss may be represented by an attenuation constant αL in units of inverse meter (1/m). The attenuation constant is positive for a lossy media, zero for a lossless media, and negative for a media with gain. For one-dimension, the defining differential equation for the irradiance (irradiance I with units of W/m2) amplitude is dI/dx = - αLI. The solution is I = Io exp(- αLx) Where Io is the value of I at the position (x=0). This loss does not include reflection loss at interfaces. Care must be taken to distinguish between the exponential loss constant for irradiance and that for fields. The attenuation constant αL as defined here refers to irradiance. The corresponding exponential loss constant for fields is αL/2. Some texts, especially in the semiconductor field, will define the absorption coefficient (αL) for irradiance with units of inverse meters (m-1) or inverse centimeters (cm-1) while optics or fields text will use define an equivalent quantity for field attenuation, i.e. equivalent to αL/2. Note that the terminology and symbol notation are sometimes used interchangeably in the literature. © Watkins 2009 MISSOURI S&T Page 23 of 30 PN PHOTODIODES Photodiode – an optoelectronic device that is based on a semiconductor junction which absorbs light and converts the light input to a current. Incident photons are absorbed through upward bandgap transitions Photon-induced carriers contribute to the drift current if absorbed within or at the edge of the transition region W. Photodiode current I = I0 [exp(qV/kT) – 1] – ILight Photon-generated current ILight = ηqPλ/hc where η = efficiency = carriers generated per incident photon q = charge per carrier P = optical power absorbed (J/s) hc/λ = energy per incident photon (J/photon) note: Pλ/hc = incident photons per second Photoconductive mode – the current-voltage behavior for reverse bias (negative V) depends on the incident light. I Reverse bias with V 1 (one photon gives many carriers by avalanche gain) Example Structure E x junction p+ p- p n+ p+ p- p n+ Design Thin p+ region to allow light to reach the transition region n+ region provide electrons as the primary carrier (faster than holes) p- transition region width matched to absorption needs (from αL) Separate p multiplication region with large electric field © Watkins 2009 MISSOURI S&T Page 27 of 30 LIGHT EMITTING DIODES Emission: A process that converts energy into light. Injection Electroluminescence A “direct-bandgap” semiconductor such as GaAs (Si and GE are indirect semiconductors and do not emit light) Injected carriers recombine with a light-emitting transition. The transition can be spontaneous or stimulated and occurs near the edges of the depletion region in a diode structure. Light Emitting diode (LED): an optoelectronic device that emits non-coherent optical radiation at a photon energy close to bandgap of the junction. Structure: Typically a p+n or n+p diode such that the main transitions occur on the n-side or p-side respectively of the depletion region. Operation: Forward-bias effect producing spontaneous emission. Example Band Structure for n+p diode (Forward Bias) p-type Region n-type Region Structure Junction - + - + - + W The current is primarily electron flow and the main recombination region is the edge of the depletion region on the p-side. The optical output increases with forward-bias diode current. An important issue is the re-absorption of emitted photons. Heterostructures (the use of semiconductors with different bandgaps) are often used such that the photons are emitted in a small bandgap semiconductor and exit the diode through a larger bandgap semiconductor. © Watkins 2009 MISSOURI S&T Page 28 of 30 LASER DIODES LASER or Laser: light amplification by stimulated emission radiation. A process that emits optical radiation which is coherent, highly directional, and nearly monochromatic. The spectral purity of laser light is a key property, i.e. the output for a laser has an extremely small spectrum (wavelength spread). Lasing Operation Active material – A material in which energy is converted into light Pumping Mechanism – A mechanism to excite ions, electrons, or molecules so that a light-emitting transition is produced. Resonant Cavity – A structure to produce optical feedback, i.e. light is amplified through stimulated emission verses spontaneous emission. Laser diode (LD): an optoelectronic device that is based on a semiconductor junction which emits optical laser radiation at a photon energy close to bandgap of the junction. Active Material – Direct-bandgap Semiconductors Pumping Mechanism – Diode Junction Structure (Injection Electroluminescence). Heterostructures are common. Resonant Cavity – A Waveguide Structure combined with End-face Mirrors Typical Output Characteristic (Forward Bias) Optical Output Power Threshold Current Diode Current The Threshold current is the diode current needed to produce stimulated emission, i.e. it is the onset of lasing. A laser diode is highly efficient in that it converts a high fraction of the electrical energy into useful optical output. © Watkins 2009 MISSOURI S&T Page 29 of 30 EXAMPLES © Watkins 2009 MISSOURI S&T Page 30 of 30