Large Intensity Fluctuations for Wave Propagation in Random Media

Shapiro, Boris

doi:10.1103/physrevlett.57.2168

Cited by 298 publications

(178 citation statements)

References 12 publications

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“…Compared to the unperturbed case, the random dielectric potential leads to an additional term ⌺, called the self-energy, which takes into account the correlation induced by disorder in the averaging process of the field. For a homogeneous random medium and in the leading approximation, 19 the self-energy is given by ⌺͑k͒ =−i͑ 0 / cl͒. In such media, the dispersion relation is all the more affected that the mean-free path l is small; i.e., that the random fluctuations of the disordered potential are large.…”

Section: A Dispersive Regimementioning

confidence: 99%

“…In the so-called ladder approximation, the determination of the second moment ͗ ͑ 1 , k 1 ͒ ‫ء‬ ͑ 2 , k 2 ͒͘ of the field from the BetheSalpeter equation, shows that the average intensity at a given spatial point is the sum of the Drude-Boltzmann contribution and a contribution known as the ''diffuson'' contribution. 19,21 The former contribution, that has an exponential decay and can be neglected after several mean-free path l, corresponds to the dispersive regime. 2,18 The latter contribution corresponds to the multiple-scattering regime and is associated with the formation of speckles in the spatial frequency spectrum.…”

Section: B Diffusive Regimementioning

confidence: 99%

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Light transport regimes in slow light photonic crystal waveguides

et al. 2009

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The dispersive properties of waves are strongly affected by inevitable residual disorder in man-made propagating media, in particular in the slow wave regime. By a direct measurement of the dispersion curve in k space, we show that the nature of the guided modes in real photonic crystal waveguides undergoes an abrupt transition in the vicinity of a band edge. Such a transition that is not highlighted by standard optical transmission measurement, defines the limit where k can be considered as a good quantum number. In the framework of a mean-field theory we propose a qualitative description of this effect and attribute it to the transition from the "dispersive" regime to the diffusive regime. In particular we prove that a scaling law exists between the strength of the disorder and the group velocity. As a result, for group velocities v g smaller than c / 25 the diffusive contribution to the light transport is predominant. In this regime the group velocity v g loses its relevance and the energy transport velocity v E is the proper light speed to consider.

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Section: A Dispersive Regimementioning

confidence: 99%

Section: B Diffusive Regimementioning

confidence: 99%

Light transport regimes in slow light photonic crystal waveguides

et al. 2009

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“…[6,7]). When considering FCF slow coordinate r = (r 1 + r 2 )/2 and time t = (t 1 + t 2 )/2 as well as fast ones: ρ = (r 1 − r 2 )/2 and τ = (t 1 − t 2 )/2 are introduced.…”

Section: Definitions and Statement Of The Problemmentioning

confidence: 99%

“…This activity was inspired by experimental evidence for a number of the phenomena (e.g. enhanced back-scattering [1,2], spatial and frequency correlation of back-scattered and transmitted radiation [3,4]; for a review see [5]) as well as by realizing a close similarity of these phenomena to fluctuation phenomena in electron transport in disordered systems (mesoscopics) [6,7]. The latter brought new physical insight and theoretical methods into the field established in optics many years ago [8].…”

Section: Introductionmentioning

confidence: 99%

Long-time asymptotic of temporal-spatial coherence function for light propagation through time dependent disorder

Auslender

1997

Physics Letters A

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Long-time asymptotic of field-field correlator for radiation propagated through a medium composed of random point-like scatterers is studied using Bete-Salpeter equation. It is shown that for plane source the fluctuation intensity (zero spatial moment of the correlator) obeys a power-logarithmic stretched exponential decay law, the exponent and preexponent being dependent on the scattering angle. Spatial center of gravity and dispersion of the correlator (normalized first and second spatial moments, respectively) prove to weakly diverge as time tends to infinity. A spin analogy of this problem is discussed.

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“…The diffusion approach also describes the transport of classical and quantum waves in multiply scattering media [2][3][4][5][6][7][8][9][10][11][12][13][14][15][16][17][18][19][20] . Waves entering a static disordered sample interfere to produce a wavelength-scale speckled pattern of energy or particle density that is a unique fingerprint of the wave interaction with the disordered sample.…”

mentioning

confidence: 99%

Diffusion in Translucent Media

Genack

Shi

2018

Conference on Lasers and Electro-Optics

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Diffusion is the result of repeated random scattering. It governs a wide range of phenomena from Brownian motion, to heat flow through window panes, neutron flux in fuel rods, dispersion of light in human tissue, and electronic conduction. It is universally acknowledged that the diffusion approach to describing wave transport fails in translucent samples thinner than the distance between scattering events such as are encountered in meteorology, astronomy, biomedicine, and communications. Here we show in optical measurements and numerical simulations that the scaling of transmission and the intensity profiles of transmission eigenchannels have the same form in translucent as in opaque media. Paradoxically, the similarities in transport across translucent and opaque samples explain the puzzling observations of suppressed optical and ultrasonic delay times relative to predictions of diffusion theory well into the diffusive regime.

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Large Intensity Fluctuations for Wave Propagation in Random Media

Cited by 298 publications

References 12 publications

Light transport regimes in slow light photonic crystal waveguides

Light transport regimes in slow light photonic crystal waveguides

Long-time asymptotic of temporal-spatial coherence function for light propagation through time dependent disorder

Diffusion in Translucent Media

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