Open Transmission Channels: A Window for Imaging in Scattering Media

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  • hochgeladen 4. März 2020

Random scattering of light, which takes place in paper, paint and biological tissue is an obstacle to imaging and focusing of light and thus hampers many applications. At the same time scattering is a phenomenon of basic physical interest as it allows the study of fascinating interference effects such as open transport channels [1,2], which enable lossless transport of waves through strongly scattering materials. These speckle correlation effects are associates with a relatively broad bandwidth [3], raising the question whether they are associated with light that has undergone a less-than average number of scattering events. A thorough understanding of these open channels and the correlations between scattered and ballistic waves may help high-resolution [4] and prior-information-based [5] imaging methods to be generalized to volume scattering media. Ultimately, such methods are envisioned to extend the operational depth of tissue optics methods such as multiphoton imaging or OCT. 
 

 

  • [1]  A. P. Mosk, A. Lagendijk, G. Lerosey, and M. Fink, Controlling waves in space and time for imaging and focusing in complex media, Nat. Photon., 6, 283 (2012).
  • [2]  I.M. Vellekoop and A.P. Mosk, Universal optimal transmission of light through disordered materials, Phys. Rev. Lett. 101, 120601 (2008).
  • [3]  Jeroen Bosch, Sebastianus A. Goorden, and Allard P. Mosk, Frequency width of open channels in multiple scattering media, Opt. Expr. 24, 26472-26478 (2016)
  • [4]  H. Yılmaz, E. G. van Putten, J. Bertolotti, A. Lagendijk, W. L. Vos, and A. P. Mosk, Exploiting speckle cor- relations to improve the resolution of wide-field fluorescence microscopy, Optica 2, 424 (2015)
  • [5]  X. Xu, X. Xie, A. Thendiyammal, H. Zhuang, J. Xie, Y. Liu, J. Zhou, and A. P. Mosk, Imaging of objects through a thin scattering layer using a spectrally and spatially separated reference, Opt. Express 26 (12), 15073–15083 (2018). 
Kategorien: Physik, Kolloquium
Referent/in:

Prof. Dr. Allard Mosk


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