What is Em waves: Definition and 226 Discussions

In physics, electromagnetic radiation (EM radiation or EMR) refers to the waves (or their quanta, photons) of the electromagnetic field, propagating through space, carrying electromagnetic radiant energy. It includes radio waves, microwaves, infrared, (visible) light, ultraviolet, X-rays, and gamma rays. All of these waves form part of the electromagnetic spectrum.Classically, electromagnetic radiation consists of electromagnetic waves, which are synchronized oscillations of electric and magnetic fields. Electromagnetic radiation or electromagnetic waves are created due to periodic change of electric or magnetic field. Depending on how this periodic change occurs and the power generated, different wavelengths of electromagnetic spectrum are produced. In a vacuum, electromagnetic waves travel at the speed of light, commonly denoted c. In homogeneous, isotropic media, the oscillations of the two fields are perpendicular to each other and perpendicular to the direction of energy and wave propagation, forming a transverse wave. The wavefront of electromagnetic waves emitted from a point source (such as a light bulb) is a sphere. The position of an electromagnetic wave within the electromagnetic spectrum can be characterized by either its frequency of oscillation or its wavelength. Electromagnetic waves of different frequency are called by different names since they have different sources and effects on matter. In order of increasing frequency and decreasing wavelength these are: radio waves, microwaves, infrared radiation, visible light, ultraviolet radiation, X-rays and gamma rays.Electromagnetic waves are emitted by electrically charged particles undergoing acceleration, and these waves can subsequently interact with other charged particles, exerting force on them. EM waves carry energy, momentum and angular momentum away from their source particle and can impart those quantities to matter with which they interact. Electromagnetic radiation is associated with those EM waves that are free to propagate themselves ("radiate") without the continuing influence of the moving charges that produced them, because they have achieved sufficient distance from those charges. Thus, EMR is sometimes referred to as the far field. In this language, the near field refers to EM fields near the charges and current that directly produced them, specifically electromagnetic induction and electrostatic induction phenomena.
In quantum mechanics, an alternate way of viewing EMR is that it consists of photons, uncharged elementary particles with zero rest mass which are the quanta of the electromagnetic field, responsible for all electromagnetic interactions. Quantum electrodynamics is the theory of how EMR interacts with matter on an atomic level. Quantum effects provide additional sources of EMR, such as the transition of electrons to lower energy levels in an atom and black-body radiation. The energy of an individual photon is quantized and is greater for photons of higher frequency. This relationship is given by Planck's equation E = hf, where E is the energy per photon, f is the frequency of the photon, and h is Planck's constant. A single gamma ray photon, for example, might carry ~100,000 times the energy of a single photon of visible light.
The effects of EMR upon chemical compounds and biological organisms depend both upon the radiation's power and its frequency. EMR of visible or lower frequencies (i.e., visible light, infrared, microwaves, and radio waves) is called non-ionizing radiation, because its photons do not individually have enough energy to ionize atoms or molecules or break chemical bonds. The effects of these radiations on chemical systems and living tissue are caused primarily by heating effects from the combined energy transfer of many photons. In contrast, high frequency ultraviolet, X-rays and gamma rays are called ionizing radiation, since individual photons of such high frequency have enough energy to ionize molecules or break chemical bonds. These radiations have the ability to cause chemical reactions and damage living cells beyond that resulting from simple heating, and can be a health hazard.

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  1. J

    Why are EM waves blocked by non-conductors?

    My father-in-law uses a USB internet stick for his internet since he lives in The Middle of Nowhere where there is no cable nor DSL. His problem is that reception from his basement office is very poor. However, reception from the second floor of his house is okay... I don't understand this...
  2. W

    Average intensity problem? related to EM waves?

    Homework Statement The helium-neon lasers that we use in lab produce light waves with an average power of 0.85 mW. Suppose that at a distance of 1.0 m from the laser the beam has a diameter of 1.1 mm. a) What is the average intensity of the laser beam 1.0 m from the laser? b) What is the...
  3. M

    Question about energy in EM waves

    The instantaneous energy density of a region of space of an EM wave is: u = \epsilon0E2 [J/m^3] hence the average energy density is: uavg = (1/2)\epsilon0E02 [J/m^3] uavg = <S> / c [J/m^3] Is this equal to the wave's average http://en.wikipedia.org/wiki/Radiation_pressure"...
  4. D

    Do Fresnell equations apply to other waves than EM waves?

    When I read about Fresnel equations, I see that it is based on boundary equations determined by Maxwell's equations. So I would think these equations only apply to EM waves. But is there a similar behavior in other waves like sound waves in water? Would I want to use or modify Fresnel...
  5. R

    EM Waves and Dielectric interfaces

    Homework Statement Re‐write the formula E = Eo cos (k• r −ωt) for each of the three waves, in terms of the angles θi, θr and θt and the dielectric constants ni and nt (for the materials on the left and the right) in place of k The incident wave is in the xy plane only as is therefore...
  6. S

    The Doppler Effect For EM Waves

    Homework Statement A star is moving away from Earth at a speed of 2.4 x 10^8 m/s. Light of wavelength 480 nm is emitted by the star. What is the wavelength as measured by an Earth observer?Homework Equations fo=fs(1 - vrel/c) I substracted because they the star is moving away from the earth...
  7. H

    EM waves amplitude's effecting penetration?

    If you held frequency constant, and changed the amplitude of EM waves coming from a source, then would the distance into a material the EM waves would penetrate change?
  8. M

    Separating Electricity and Magnetism from EM Waves

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  9. S

    Understanding EM Wave Attenuation in Conductors and Dielectrics

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  10. K

    EM Waves Penetration: Frequency Effects & Atmospheric Limitations

    When an EM wave has a higher frequency, it is able to penetrate materials more easily. However, why does a microwave able to penetrate haze while visible light can't? Why visible light is able to enter our atmosphere while those of gamma can't?
  11. L

    Welcome! Ask Away: How Electrons Orbit Without EM Waves

    Hi Everyone! I'm new here and like this forum. Can anyone tell me how the electron moving roundly in atom doesn't emit EM waves while changing it's speed?
  12. I

    Hertz and polarization of EM waves

    Hi, I'm having difficulty understanding exactly how the reciever loop detects the EM waves in this experiment and I can't find any definitive information online. My understanding is that since EM waves are transverse, to be absorbed by the receiving electrodes, the length of the molecule chains...
  13. fluidistic

    Sum of 2 EM Waves w/ Same Phase & Amp but Diff Freq

    Homework Statement Describe the sum of two EM waves that have the same initial phase and same amplitude but different frequencies such that \omega _1 >> \omega _2.Homework Equations E=E_0 \cos (kx -\omega t + \alpha).The Attempt at a Solution I summed them up and reached, after an...
  14. fluidistic

    Prove: EM Waves Addition Superposition Equivalence

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  15. fluidistic

    Can the amplitude of an EM wave affect its physical size?

    In the case of plane waves, E is orthogonal to B and they're both orthogonal to the direction of propagation, call it k. I'm not sure I'm picturing well what such an EM wave is. For instance I know that E and B oscillates with respect to time. Without looking to quantum electrodynamics that...
  16. I

    How Does Electronic Susceptibility Affect EM Signal Propagation in a Dielectric Medium?

    In general the electronic susceptibility, χ, is a function of frequency and is complex for a dielectric medium. So what are the implications of this for the propagation of EM signals in a dielectric medium? Since the electronic susceptibility varies with refractive index, and the refractive...
  17. S

    What is the extent of the electric field in electromagnetic waves?

    Hello. Just a noob question about electromagnetic waves. An electron "wiggles" and sends out a change in electric field, which creates a change in magnetic field, which creates a change in electric field etc etc. My question is, because the photon travels to virtually infinite distances...
  18. K

    Does E=cB Hold for All EM Waves?

    I know for spherical or plane EM wave, there's relation E=cB, and we can prove it by the explicit expression of these two kinds of wave. But does E=cB hold for all EM waves, e.g. all possible wavelike solutions of maxwell's equation?
  19. Z

    Differences Between EM Waves & Pulses: Comprehensive Analysis

    What is the difference between EM Waves and EM Pulses and how are they related to one another? When trying to look up info on this, I always get a full article on either just one or the other so that no comparison is ever made between one and the other, the definitions alone seem a little...
  20. R

    Can EM Waves Vibrate Powders? Exploring Physical Effects

    Can man-made EM waves produce physical vibrations of objects? Can man-made EM waves vibrate powders like sand or talc? I'm trying to understand if any types of electronic frequencies can cause physical vibrations...thanks.
  21. M

    Is F. Abeles' 1950 paper on EM waves in stratified media still accessible?

    I've been trying to search for this seminal paper on EM waves in stratified media. 'Investigations on the propagation of sinusoidal electromagnetic waves in stratified media', by F. Abeles Ann. Phys. (Paris) 5, 596, 706 (1950). I cannot find it in any database. Can anyone please tell me...
  22. Q

    Frequency of Radiating EM Waves from a Moving Electron on a Unit Circle

    Let's assume that electron is moving around the unit circle. Using Maxwell equations show what is the frequency of radiating EM waves. How to start with it? What's the form of known variables - current density and charge density?
  23. B

    Interaction of EM waves with media at boundaries

    Please see the diagram attached, I don't understand how my lecturer is resolving the E-field in the perpendicular case. He obtains: E_i = \bold{y} e^{-i\omega(t - \frac{n_1}{c} (-xsin \theta_i - z cos \theta_i))} How has he obtained the (-xsin \theta_i - z cos \theta_i) part from that...
  24. M

    EM waves in matter (electrodynamics)

    I'm having some trouble understanding this module. It would be great if anyone could help. In a homogeneous nonconduction region where μr = 1, find εr and ω if E=30(pi)e[i(ωt-4/3y)] in z direction H=0.1e[i(ωt-4/3y)] in x direction I am to understand that for a homognous nonconduction region...
  25. C

    Shouldn't a DC current emit EM waves?

    So in a DC current we have a relative uniform movement of electrons in one direction. If we would have a very narrow coil around the dc current carrying wire, (like an atom wide), every time an electron pass trough the plan of the coil, should induce a voltage in the coil, so theoretically we...
  26. M

    Lattice Vibrations and em waves

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  27. D

    How do EM waves transfer energy?

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  28. S

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  29. J

    Uncovering Heinrich Hertz: The First to Generate EM Waves in a Lab

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  30. J

    How Does Temperature Affect Electromagnetic Waves?

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  31. I

    Frequency of EM Waves in an LC Circuit

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  32. T

    Understanding Reflection and Ion Movement in EM Waves

    1. Since skin depth is the attenuation of the wave in a conductor, this means the reflection isen't the incident wave... so what is the reflection? 2. Water doesn't stop light since it's frequency is too high, i saw on forum it's because the big ions can't move fast enought. How can that be...
  33. W

    Reflection and Transmission of EM waves

    Hi all, I was reading "Geometrical Optics Reflected Fields" chapter from "Introduction to Uniform Geometrical Theory of Diffraction" textbook. The author assumed that the surface is perfectly conducting and therefore he only considered the reflected waves. He derived a formula for the...
  34. R

    "Intensity of Incoherent EM Waves

    Homework Statement Two incoherent EM waves of intensities 7I0 and 13I0 travel in the same direction in the same region of space. What is the intensity of EM radiation in this region? Homework Equations The Attempt at a Solution I have tried using I = I1 + I2 + ( 2* square root of...
  35. K

    Transimission Of EM waves in conductors at an angle of incidence

    We know that in electrodynamic when an incident Electromagnetic wave strikes a charged barrier it can either be reflected or transmits. And both of the incident, reflected and transmitted waves are in the same plane called plane of incidence. Now, i met a problem in which they state that the...
  36. rjbeery

    EM Waves Vs Photons: Can Physical Explanations Explain All?

    Are there any EM wave behaviors that cannot be explained in a purely physical, "photonic" manner? I'm speaking specifically of the photon's path from emitter to absorber, irrespective of "why" that path was taken (in other words, the double-slit experiment does not qualify in the context of my...
  37. M

    Comparing Photons & EM Waves in Physics

    I am trying to review some basic physics, purely for my own interest, and have been looking at particle physics in the form of the Bohr model and EM theory in the form of Maxwell’s equation. While I still have a way to go on these topics, I was wondering if anybody is in a position to help me...
  38. N

    Proving EM Waves Equations: E = Emsin(kx-ωt) and B = Bmsin(kx-ωt)

    Show that the electric field: E = Emsin(kx-ωt) and magnetic field: B=Bmsin(kx-ωt) satisfy the following equations: -\frac{\partial B}{\partial x} = \mu_{0}\epsilon_{0}\frac{\partial E}{\partial t} and \frac{\partial E}{\partial x} = -\frac{\partial B}{\partial t} I have no idea...
  39. T

    Exploring Warp Drive Possibilities with EM Waves

    I love Star trek and I was thinking, how to create a warp drive. I have read a discusion about EM waves on this forum, there was written that they do not need any medium for propagation and : “In a simplified sense the oscillating E field sustains the oscillating B field which sustains the...
  40. K

    What is the Relationship Between EM Wave Velocity and Electric Field in Space?

    Homework Statement Find the velocity of EM waves as a function of \epsilon_{0} and \mu_{0} 2. The attempt at a solution E = E_{0}cos(kx-\omega t) Using v= \frac{\omega}{k}
  41. H

    Sketching EM Waves with imaginary amplitudes

    Homework Statement Sketch in 3D, the following waves. (both E fields are in x direction E_1 = 3*exp(-j*8*Pi*z) E_2 = 4j*exp(-j*8*Pi*z) (where j=sqrt(-1)The Attempt at a Solution I know how to sketch E_1, but my question is how to treat the imaginary amplitude, 4j in E_2. here is my stab at...
  42. S

    Effects em fields have on em waves

    Ok my question is pretty simple and is in two parts. 1. say you created an em field what would have to an em wave the is propogating towards it. 2. what would would to an em wave if it went through an em coil. If you could would you be able to point me in the direction a...
  43. N

    EM waves - wave equation derivation

    Hi, Something has been bothering me about deriving the wave equation for a plane EM wave. We were showed this derivation in class and had to reproduce it but something is not making sense to me... The derivation is as follows: Suppose you have a plane EM wave (in a vaccuum) traveling in the...
  44. J

    Why do different frequency EM Waves behave different ?

    Hi, i was wondering Sorry if i don't have the right words, i study in France Why are Microwaves better for heating up food ? I mean since E=hv, these should contain less energy Right now, i know vaguely, that atoms absorb photons where the energy can make it go from one of its characteristic...
  45. J

    How can an antenna capture + receive EM Waves ?

    Hi I was wondering how can antennas capture + receive Electromagnetic waves I was thinking, in particular of FM Transmitters Antennas, and Fm receiver Antennas. And also, how come metals act as a shield to EM Waves I know that antennas have a resistance, and that they consume Energy by...
  46. H

    Exploring the Interaction of EM Waves & Molecular Vibrations

    Quote from Organic Chemistry, L.G. Wade, Jr.: "Not all molecular vibrations absorb IR radiation." "One of the component of an electromagnetic wave is E field. This field alternately stretches and compresses a polar bond." "If this alternate stretching compressing of the bond occurs at the...
  47. T

    Deriving Poynting Vector from EM Waves

    can anyone help me derive the poynting vector from energy density of electromagnetic waves? and how we obtain average value <S> thanks
  48. S

    Is there any truth to this? FTL Gravity and EM Waves

    http://www.youtube.com/watch?v=5wnk6FVXCmc&feature=related That is one of several parts, 4 or 5 I believe. So is there any real science or truth to what he is saying? If he is correct it could quite possibly be the most important discovery in human history. Mind you, I'm not talking so...
  49. B

    EM Waves: Understanding w/o Quantum Mechanics?

    Another thing that I've never really understood... As fas as I'm concerned, waves need a medium to travel through, but electromagnetic waves seem not to need one at all. I just can't visualise them as oscillations in anything. It sort of helps if I visualise EM waves as photons, because then...
  50. marcus

    Hints of dispersion (both gravity and EM waves)

    This paper which just appeared on arxiv http://arxiv.org/abs/0709.2365 Loop quantum gravity corrections to gravitational wave dispersion Martin Bojowald, Golam Mortuza Hossain 27 pages (Submitted on 14 Sep 2007) "Cosmological tensor perturbations equations are derived for Hamiltonian cosmology...
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