![]() Symmetry properties and polarization descriptors for an arbitrary electromagnetic wavefield. Jones and Stokes parameters for polarization in three dimensions. Polarimetric characterization of light and media. Geometric interpretation of the three-dimensional coherence matrix for nonparaxial polarization. Degree of polarization for optical near fields. Parameters characterizing electromagnetic wave polarization. Principles of Nano-Optics (Cambridge Univ. Quantum Electrodynamics (Pergamon, 1982). Ellipsometry and Polarized Light (North-Holland, 1977).īerestetskii, V. Electromagnetic Vibrations, Waves, and Radiation. ^ Bekefi, George Barrett, Alan (1977).United States of America: Addison Wesley. "Density Operator of Unpolarized Radiation". ^ Prakash, Hari Chandra, Naresh (1971).Optical Sciences and Applications of Light. Coherence (physics)#Polarization and coherence.This property, which can only be true when pure polarization states are mapped onto a sphere, is the motivation for the invention of the Poincaré sphere and the use of Stokes parameters, which are thus plotted on (or beneath) it. The overlap between any two polarization states is dependent solely on the distance between their locations along the sphere. When plotted, that point will lie on the surface of the unity-radius Poincaré sphere and indicate the state of polarization of the polarized component.Īny two antipodal points on the Poincaré sphere refer to orthogonal polarization states. One such representation is the coherency matrix: : 137–142 Ψ = ⟨ e e † ⟩ = ⟨ ⟩ = ⟨ ⟩ In so-called partially polarized radiation the fields are stochastic, and the variations and correlations between components of the electric field can only be described statistically. However any mixture of waves of different polarizations (or even of different frequencies) do not correspond to a Jones vector. The Jones vector perfectly describes the state of polarization and phase of a single monochromatic wave, representing a pure state of polarization as described above. Mueller matrices are then used to describe the observed polarization effects of the scattering of waves from complex surfaces or ensembles of particles, as shall now be presented. While every Jones matrix has a Mueller matrix, the reverse is not true. ![]() Such matrices were first used by Paul Soleillet in 1929, although they have come to be known as Mueller matrices. For these cases it is usual instead to use a 4×4 matrix that acts upon the Stokes 4-vector. So-called depolarization, for instance, cannot be described using Jones matrices. ![]() However, in practice there are cases in which all of the light cannot be viewed in such a simple manner due to spatial inhomogeneities or the presence of mutually incoherent waves. The transmission of plane waves through a homogeneous medium are fully described in terms of Jones vectors and 2×2 Jones matrices. However, in order to also describe the degree of polarization, one normally employs Stokes parameters to specify a state of partial polarization. That polarized component can be described in terms of a Jones vector or polarization ellipse. : 346–347 : 330 One may then describe the light in terms of the degree of polarization and the parameters of the polarized component. At any particular wavelength, partially polarized light can be statistically described as the superposition of a completely unpolarized component and a completely polarized one. Light is said to be partially polarized when there is more power in one of these streams than the other. Unpolarized light can be described as a mixture of two independent oppositely polarized streams, each with half the intensity. Ī so-called depolarizer acts on a polarized beam to create one in which the polarization varies so rapidly across the beam that it may be ignored in the intended applications.Ĭonversely, a polarizer acts on an unpolarized beam or arbitrarily polarized beam to create one which is polarized. Ĭonversely, the two constituent linearly polarized states of unpolarized light cannot form an interference pattern, even if rotated into alignment ( Fresnel–Arago 3rd law). Unpolarized light can be produced from the incoherent combination of vertical and horizontal linearly polarized light, or right- and left-handed circularly polarized light. Natural light, like most other common sources of visible light, is produced independently by a large number of atoms or molecules whose emissions are uncorrelated. ![]() Unpolarized light is light with a random, time-varying polarization.
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