Multiple scattering of classical waves: microscopy, mesoscopy, and diffusion

Rossum, Mark C. W. van; Nieuwenhuizen, Th. M.

doi:10.1103/revmodphys.71.313

Cited by 742 publications

(843 citation statements)

References 107 publications

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“…This implies statistical independence of these paths which is generally accepted to be true for kl * >> 1 [17]. The discussion of phase matching in the case of dilute suspension at the end of the previous section also applies (with evident modifications) in the case of concentrated suspension, requiring (a) complete disorder in particle positions and (b) large (>> λ) interparticle distance for our analysis to hold.…”

Section: Shg By a Concentrated Suspension Of Spherical Particlesmentioning

confidence: 87%

Second harmonic generation in suspensions of spherical particles

Makeev

Skipetrov

2003

Optics Communications

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We study the second harmonic generation (SHG) in a suspension of small spherical particles confined within a slab, assuming undepleted pump and applying (i) single scattering approximation and (ii) diffusion approximation. In the case (i), the angular diagram, the differential and total crossections of the SHG process, as well as the average cosine of SH scattering angle are calculated. In the case (ii), the average SH intensity is found to show no explicit dependence on the linear scattering properties of the suspension. The average intensity of SH wave scales as I 0 L/Λ 2 in both cases (i) and (ii), where I 0 is the intensity of the incident wave, L is the slab thickness, and Λ 2 is an intensity-dependent "SH scattering" length.1

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Section: Shg By a Concentrated Suspension Of Spherical Particlesmentioning

confidence: 87%

Second harmonic generation in suspensions of spherical particles

Makeev

Skipetrov

2003

Optics Communications

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“…It is well known that the diffuse lifetime in finite systems should scale as τ D ∝ (L + 2z e ) 2 , where z e is the so-called "extrapolation length" [5]. Since z e = 2 3 t for three-dimensional systems with index matched boundaries (neglecting internal reflections) [31], when L t the contribution of z e to L e is negligible (L e L) and thus z = d w = 2. However, for our homogeneous sample with t = 40 µm and thicknesses in the range 230 ≤ L ≤ 450 µm, we expect a difference between z and d w .…”

Section: B Lifetime Scaling With Sample Thicknessmentioning

confidence: 99%

Walk dimension for light in complex disordered media

Savo

Burresi²,

Svensson³

et al. 2014

Phys. Rev. A

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Transport in complex systems is characterized by a fractal dimension -the walk dimension -that indicates the diffusive or anomalous nature of the underlying random walk process. Here we report on the experimental retrieval of this key quantity, using light waves propagating in disordered media. The approach is based on measurements of the time-resolved transmission, in particular on how the lifetime scales with sample size. We show that this allows one to retrieve the walk dimension and apply the concept to samples with varying degree of fractal heterogeneity. In addition, the method provides the first experimental demonstration of anomalous light dynamics in a random medium.

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“…Closely related numerical techniques based on the analysis of the eigenstates of the coupled system of the light and the atoms [15,[27][28][29][30][31][32] or density matrices and quantum trajectories [33][34][35] are also widely used today. Other ideas drawn from the theory of radiative transfer [36,37] and multiple scattering [38,39], enhanced with numerics, also have potential to make inroads into the questions about light propagation in atomic media [40].…”

Section: Introductionmentioning

confidence: 99%

Exact electrodynamics versus standard optics for a slab of cold dense gas

Javanainen

Ruostekoski

et al. 2017

Phys. Rev. A

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We study light propagation through a slab of cold gas using both the standard electrodynamics of polarizable media and massive atom-by-atom simulations of the electrodynamics. The main finding is that the predictions from the two methods may differ qualitatively when the density of the atomic sample ρ and the wave number of resonant light k satisfy ρk −3 1. The reason is that the standard electrodynamics is a mean-field theory, whereas for sufficiently strong light-mediated dipole-dipole interactions the atomic sample becomes strongly correlated. The deviations from mean-field theory appear to scale with the parameter ρk −3 , and we demonstrate noticeable effects already at ρk −3 10 −2 . In dilute gases and in gases with an added inhomogeneous broadening the simulations show shifts of the resonance lines in qualitative agreement with the predicted Lorentz-Lorenz shift and "cooperative Lamb shift," but the quantitative agreement is unsatisfactory. Our interpretation is that the microscopic basis for the local-field corrections in electrodynamics is not fully understood.

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Multiple scattering of classical waves: microscopy, mesoscopy, and diffusion

Cited by 742 publications

References 107 publications

Second harmonic generation in suspensions of spherical particles

Second harmonic generation in suspensions of spherical particles

Walk dimension for light in complex disordered media

Exact electrodynamics versus standard optics for a slab of cold dense gas

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