Glossary

are fascinating phenomena that combine electric and magnetic fields. They propagate through space at the , carrying energy and information across vast distances. Understanding their properties is crucial for grasping how modern technology works.

describe the behavior of electromagnetic waves, revealing their nature as self-sustaining oscillations of electric and magnetic fields. These waves can be produced by accelerating charges and detected through various methods, enabling a wide range of applications from radio communication to medical imaging.

Plane Electromagnetic Waves

Electromagnetic wave components and propagation

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  • In a , the electric field (E\vec{E}), (B\vec{B}), and (k\vec{k}) are mutually perpendicular to each other
    • E\vec{E} and B\vec{B} oscillate in phase with each other, meaning their peaks and troughs align at the same points in space and time
    • The direction of propagation is given by the cross product of E\vec{E} and B\vec{B}: k=E×BEB\vec{k} = \frac{\vec{E} \times \vec{B}}{|\vec{E}||\vec{B}|}, which is a vector perpendicular to both E\vec{E} and B\vec{B}
      • This relationship is often represented by the "right-hand rule" (point fingers of right hand in direction of E\vec{E}, curl fingers toward B\vec{B}, thumb points in direction of k\vec{k})
    • The orientation of the electric field oscillations determines the wave's polarization

Maxwell's equations and light speed

  • Maxwell's equations describe the relationships between E\vec{E}, B\vec{B}, and k\vec{k} in electromagnetic waves
    • : ×E=Bt\nabla \times \vec{E} = -\frac{\partial \vec{B}}{\partial t} states that a changing magnetic field induces an electric field (electric generator)
    • with Maxwell's correction: ×B=μ0(J+ε0Et)\nabla \times \vec{B} = \mu_0\left(\vec{J} + \varepsilon_0\frac{\partial \vec{E}}{\partial t}\right) states that a changing electric field and electric current induce a magnetic field (electromagnet)
    • for electric fields: E=ρε0\nabla \cdot \vec{E} = \frac{\rho}{\varepsilon_0} states that electric fields originate from electric charges (point charges)
    • Gauss's law for magnetic fields: B=0\nabla \cdot \vec{B} = 0 states that magnetic fields have no divergence, meaning there are no magnetic monopoles (bar magnets always have north and south poles)
  • In , where there are no charges (ρ=0\rho = 0) or currents (J=0\vec{J} = 0), Maxwell's equations simplify and lead to wave equations for E\vec{E} and B\vec{B}
    • The speed of the electromagnetic wave in both equations is given by: v=1μ0ε0v = \frac{1}{\sqrt{\mu_0\varepsilon_0}}, where μ0\mu_0 is the and ε0\varepsilon_0 is the of free space
    • Substituting known values yields: v3×108 m/sv \approx 3 \times 10^8 \text{ m/s}, equal to the in vacuum, cc
      • This result showed that light is an electromagnetic wave and unified electricity, magnetism, and optics

Electric to magnetic field ratio

  • In a plane electromagnetic wave, the ratio of the electric field magnitude to the magnetic field magnitude is constant and equal to the speed of light in free space
    • The relationship is given by: EB=c\frac{|\vec{E}|}{|\vec{B}|} = c, where c3×108 m/sc \approx 3 \times 10^8 \text{ m/s}
  • To calculate the ratio, divide the amplitude of the electric field (E0E_0) by the amplitude of the magnetic field (B0B_0): EB=E0B0\frac{|\vec{E}|}{|\vec{B}|} = \frac{E_0}{B_0}
    • For example, if E0=100 V/mE_0 = 100 \text{ V/m} and B0=3.33×107 TB_0 = 3.33 \times 10^{-7} \text{ T}, then EB=100 V/m3.33×107 T3×108 m/s=c\frac{|\vec{E}|}{|\vec{B}|} = \frac{100 \text{ V/m}}{3.33 \times 10^{-7} \text{ T}} \approx 3 \times 10^8 \text{ m/s} = c

Principles of EM wave production

  • Electromagnetic wave production:
    • Accelerating charges produce electromagnetic waves
      • Oscillating () and (AC circuits) are common sources
    • The of the produced wave matches the frequency of the charge oscillation or acceleration
      • For example, a 100 MHz oscillation produces a 100 MHz electromagnetic wave
    • The of the produced wave is related to the frequency by: λ=cf\lambda = \frac{c}{f}, where λ\lambda is wavelength and ff is frequency
      • Higher frequencies correspond to shorter wavelengths (), while lower frequencies correspond to longer wavelengths (radio waves)
  • Electromagnetic wave detection:
    • Electromagnetic waves are detected through their interaction with matter
      • (solar cells), (X-ray diffraction), and (PET scans) are examples
    • Antennas detect electromagnetic waves by converting oscillating electric and magnetic fields into alternating currents at the same frequency as the incident wave
      • This is the reverse process of electromagnetic wave production
    • The type of detector depends on the frequency or wavelength of the electromagnetic wave:
      1. Radio waves: antennas and receivers (AM/FM radio)
      2. : antennas, , and (microwave ovens, radar)
      3. : , bolometers, and (night vision, thermal imaging)
      4. : , , and (cameras, telescopes)
      5. , , and gamma rays: , , and (medical imaging, astronomy)

Wave properties and energy transfer

  • The describes the propagation of electromagnetic waves in space and time
  • The Poynting vector represents the energy flux density of an electromagnetic wave, indicating the direction and magnitude of energy flow
  • occurs when different wavelengths of light travel at different speeds in a medium, causing the wave to spread out
  • The is the speed at which the phase of a wave propagates in a medium

Key Terms to Review (44)

Alternating Currents: Alternating current (AC) is an electric current that periodically reverses direction, in contrast to direct current (DC) which flows in a constant direction. AC is the form in which electric power is delivered to businesses and residences, and it is the type of current used in most electric power transmission and distribution systems.
Ampère's Law: Ampère's law is a fundamental principle in electromagnetism that relates the magnetic field generated by an electric current to the magnitude and direction of that current. It is one of the four Maxwell's equations, which together describe the relationships between electric and magnetic fields and electric charges and currents.
Antennas: Antennas are devices that are designed to transmit or receive electromagnetic waves, typically for the purpose of communication or radar applications. They play a crucial role in the propagation of electromagnetic waves, converting electrical signals into electromagnetic radiation and vice versa.
Bolometers: A bolometer is a device used to measure the power of incident electromagnetic radiation. It operates by absorbing the radiation, which causes the temperature of the device to rise, and this temperature change is measured to determine the power of the radiation.
CCD sensors: CCD sensors, or Charge-Coupled Devices, are electronic devices used to capture images by converting light into electrical signals. They play a crucial role in digital imaging technology, particularly in cameras and telescopes, by enabling the detection and recording of electromagnetic waves in the visible spectrum and beyond.
Compton Scattering: Compton scattering is an inelastic scattering process in which a photon interacts with a charged particle, typically an electron, and undergoes a change in wavelength and direction. This phenomenon was first observed and explained by Arthur Compton in 1923, and it provided experimental evidence for the particle nature of electromagnetic radiation.
Dipole antenna: A dipole antenna is a radio antenna that can be made by connecting a pair of conductive elements, such as metal rods, to a transmitter or receiver. It is the simplest and most widely used type of antenna in electromagnetic wave propagation.
Dispersion: Dispersion refers to the phenomenon where different wavelengths of electromagnetic radiation travel at different velocities within a medium, causing the separation of light into its constituent spectral components. This is a fundamental property of wave propagation that has significant implications in various fields, including optics and communication systems.
Electric Dipoles: Electric dipoles are pairs of equal and opposite electric charges separated by a distance, creating a dipole moment that describes their strength and orientation. This concept is crucial in understanding the behavior of molecules in electric fields, as electric dipoles interact with external fields, leading to polarization effects and influencing the propagation of electromagnetic waves.
Electromagnetic Waves: Electromagnetic waves are a type of energy that travels through space or a medium in the form of oscillating electric and magnetic fields. These waves are responsible for various phenomena, including heat transfer, magnetism, and the propagation of electric fields, and are fundamental to our understanding of Maxwell's equations and the electromagnetic spectrum.
Faraday's law: Faraday's law states that a change in magnetic flux through a circuit induces an electromotive force (emf) in that circuit. This principle is crucial for understanding how magnetic fields interact with electric circuits and lays the foundation for many applications in electromagnetism.
Free Space: Free space refers to the region of the electromagnetic spectrum where electromagnetic waves can propagate without any physical medium or obstructions. It represents an idealized environment where waves can travel freely without being absorbed, scattered, or influenced by any materials or objects.
Frequency: Frequency is a fundamental concept in physics that describes the number of occurrences or cycles of a periodic phenomenon per unit of time. It is a crucial parameter in understanding various physical processes, including alternating current (AC) sources, power in AC circuits, electromagnetic waves, and the electromagnetic spectrum.
Gamma Rays: Gamma rays are a type of high-energy electromagnetic radiation with the shortest wavelength and highest frequency in the electromagnetic spectrum. They are produced by the radioactive decay of atomic nuclei and have the ability to penetrate deep into matter, making them useful in various applications.
Gauss's Law: Gauss's law is a fundamental principle in electromagnetism that relates the electric flux through a closed surface to the total electric charge enclosed within that surface. It provides a powerful tool for calculating the electric field produced by various charge distributions.
Half-wave antenna: A half-wave antenna is a type of dipole antenna with a length equal to half the wavelength of the frequency it is designed to transmit or receive. It is widely used because of its simplicity and efficient radiation properties.
Infrared: Infrared is a type of electromagnetic radiation with wavelengths longer than those of visible light, but shorter than those of radio waves. It is a form of thermal radiation that is invisible to the human eye, but can be detected as heat by the skin and specialized sensors.
Magnetic Field: A magnetic field is a region of space where magnetic forces can be detected. It is a fundamental concept in electromagnetism, describing the invisible lines of force that surround and permeate magnetic materials, electric currents, and changing electric fields. The magnetic field plays a crucial role in various topics within the study of college physics.
Maxwell's Equations: Maxwell's equations are a set of four fundamental equations in electromagnetism that describe the relationships between electric and magnetic fields and electric charges and currents. These equations form the foundation of classical electromagnetism and are essential for understanding a wide range of electromagnetic phenomena.
Microwaves: Microwaves are a type of electromagnetic wave with wavelengths ranging from 1 millimeter to 1 meter. They are used in various applications, including communication, radar, and cooking.
Microwaves: Microwaves are a type of electromagnetic radiation with wavelengths ranging from about 1 millimeter to 1 meter, and frequencies between 300 MHz and 300 GHz. They are an important part of the electromagnetic spectrum, with numerous applications in modern technology, including radar, telecommunications, and microwave ovens.
Pair Production: Pair production is a process in which a high-energy photon interacts with the electric field of an atomic nucleus, resulting in the creation of an electron-positron pair. This phenomenon occurs when the energy of the incident photon is at least twice the rest mass energy of an electron, which is approximately 1.02 million electron volts (MeV).
Permeability: Permeability is a measure of the ability of a material to allow the passage of a fluid, such as a magnetic field or electric current, through it. It is a fundamental property that describes how easily a material can be magnetized or how easily an electric field can be established within it.
Permittivity: Permittivity is a physical constant that describes how an electric field affects, and is affected by, a dielectric medium. It plays a crucial role in determining the strength and behavior of electric fields, influencing both the force between charges and the energy stored in capacitors. The value of permittivity varies depending on the material, affecting how electric fields interact with matter and is central to understanding capacitors and electromagnetic waves.
Phase Velocity: Phase velocity is the rate at which the phase of a wave propagates in space. It describes the speed at which the wave pattern itself moves, which can be different from the speed at which the energy or information is transmitted by the wave.
Photoconductors: Photoconductors are materials that exhibit an increase in electrical conductivity when exposed to light. They are widely used in various optoelectronic devices, such as photodetectors, solar cells, and image sensors, due to their ability to convert light energy into electrical signals.
Photodiodes: Photodiodes are semiconductor devices that convert light energy into electrical energy. They are commonly used as photodetectors, converting optical signals into electrical signals for various applications in the field of optoelectronics.
Photoelectric Effect: The photoelectric effect is a phenomenon in which electrons are emitted from the surface of a material when light or other electromagnetic radiation is incident on it. This process occurs when the energy of the incident photons is greater than the work function of the material, allowing the electrons to overcome the potential barrier and be ejected from the surface.
Photomultiplier Tubes: Photomultiplier tubes (PMTs) are highly sensitive light detectors that amplify the photons they receive into a measurable electrical signal. They work by using the photoelectric effect, where incoming light photons strike a photosensitive surface, releasing electrons that are then multiplied through a series of dynodes, resulting in a significant increase in the number of electrons and hence a stronger signal. This capability allows PMTs to detect very low levels of light, making them essential in applications like particle physics, astronomy, and medical imaging.
Plane electromagnetic wave: A plane electromagnetic wave is a type of wave that propagates through space with electric and magnetic fields oscillating perpendicular to each other and to the direction of wave propagation. This type of wave represents a fundamental concept in electromagnetism, where the fields are uniform and consistent across any plane that is perpendicular to the direction of travel.
Propagation Direction: Propagation direction refers to the path along which electromagnetic waves travel as they move through space. This direction is crucial for understanding how these waves interact with their environment, including their orientation and polarization. In the context of plane electromagnetic waves, the propagation direction helps determine how energy is transmitted through space and how waves may interfere with each other or be absorbed by different materials.
Proportional Counters: Proportional counters are gas-filled radiation detectors that measure the energy of ionizing radiation by collecting and amplifying the ion pairs produced when radiation interacts with the gas. They operate in a specific voltage range, where the output signal is directly proportional to the energy deposited by the radiation, making them useful for applications like spectroscopy and radiation dosimetry. This linear relationship allows for detailed analysis of the energy spectrum of incoming radiation.
Scintillation Detectors: Scintillation detectors are devices used to detect and measure various types of radiation, such as alpha, beta, gamma, and X-rays. They work by converting the energy from incident radiation into flashes of light, which are then converted into electrical signals that can be analyzed and quantified.
Semiconductor detectors: Semiconductor detectors are devices that utilize the properties of semiconductor materials to detect and measure various forms of radiation, including X-rays and gamma rays. These detectors convert incoming radiation into measurable electrical signals, making them crucial for applications in medical imaging, radiation monitoring, and particle physics. Their ability to provide high-resolution energy measurements is a significant advantage over other types of detectors.
Speed of light: The speed of light in a vacuum is the constant speed at which all electromagnetic waves propagate, approximately $3 \times 10^8$ meters per second. It is a fundamental constant in physics denoted by the symbol $c$.
Speed of Light: The speed of light is the maximum velocity at which all electromagnetic radiation, including visible light, can travel through a vacuum. It is a fundamental constant in physics that has profound implications across various topics in electromagnetism and relativity.
Thermocouples: Thermocouples are temperature-measuring devices that generate a small electrical voltage in response to a temperature difference between two dissimilar metal junctions. They are widely used in various applications, including the context of plane electromagnetic waves, to measure and monitor temperature changes.
Ultraviolet: Ultraviolet (UV) is a type of electromagnetic radiation with wavelengths shorter than visible light but longer than X-rays. It is a high-energy form of radiation that can have both beneficial and harmful effects on living organisms and materials.
Visible light: Visible light is the portion of the electromagnetic spectrum that is detectable by the human eye, with wavelengths ranging from approximately 400 to 700 nanometers. It plays a crucial role in various physical phenomena, including optics and thermodynamics.
Visible Light: Visible light is the portion of the electromagnetic spectrum that is visible to the human eye. It is the range of wavelengths that can be detected by the human visual system, allowing us to perceive the world around us in color.
Wave Equation: The wave equation is a second-order linear partial differential equation that describes the propagation of waves, such as sound waves, light waves, and electromagnetic waves, through a medium or in a given space. It is a fundamental equation in the study of wave phenomena and is derived from the underlying physical principles governing the behavior of waves.
Waveguides: Waveguides are hollow metal tubes or pipes designed to efficiently transmit electromagnetic waves, such as microwaves and radio waves, from one point to another. They act as a conduit, guiding the waves and preventing energy loss or interference.
Wavelength: Wavelength is the distance between two consecutive peaks or troughs in a wave. It is a fundamental property of all types of waves, including electromagnetic waves, sound waves, and water waves. Wavelength is a crucial concept in understanding the behavior and characteristics of various wave phenomena.
X-rays: X-rays are a type of high-energy electromagnetic radiation with wavelengths shorter than visible light. They are commonly used in medical imaging and industrial applications due to their ability to penetrate matter and produce detailed images.
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