Abstract

Interference of scattered waves is fundamental for modern light-scattering techniques, such as optical wavefront shaping. Recently, a new type of wavefront shaping was introduced where the extinction is manipulated instead of the scattered intensity. The underlying idea is that upon changing the phases or the amplitudes of incident beams, the total extinction will change due to interference described by the cross terms between different incident beams. Here, we experimentally demonstrate the mutual extinction and transparency effects in scattering media, in particular, a human hair and a silicon bar. To this end, we send two light beams with a variable mutual angle on the sample. Depending on the relative phase of the incident beams, we observe either nearly zero extinction, mutual transparency, or almost twice the single-beam extinction, mutual extinction, in agreement with theory. We use an analytical approximation for the scattering amplitude, starting from a completely opaque object, and we discuss the limitations of our approximation. We discuss the applications of the mutual extinction and transparency effects in various fields such as non-line-of-sight communications, microscopy, and biomedical imaging.

Highlights

  • Random scattering of light inside complex materials such as clouds, paint, milk, white-light-emiting diodes (LEDs), hair, and human tissue is what makes them appear opaque [1,2,3,4,5]

  • We measured the total extinction of two beams crossing through a scattering object, namely a human hair and a silicon bar

  • If the angle is larger, we enter, for nonopaque samples, into the speckle regime where fluctuations of the mutual extinction depend on the precise shape and distribution of the scatterers distribution in the sample

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Summary

Introduction

Random scattering of light inside complex materials such as clouds, paint, milk, white-light-emiting diodes (LEDs), hair, and human tissue is what makes them appear opaque [1,2,3,4,5]. In these inhomogeneous materials, multiple scattering and interference distort the incident wavefront so strongly that the spatial coherence is immensely reduced [6].

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