Abstract
Dielectric multilayer reflectors that are non-polarizing are an important class of optical device and have numerous applications within optical fibres1, dielectric waveguides2 and light-emitting diodes3. Here, we report analyses of a biological non-polarizing optical mechanism found in the broadband guanine-cytoplasm ‘silver’ multilayer reflectors of three species of fish. Present in the fish stratum argenteum are two populations of birefringent guanine crystal, with their optical axes either parallel to the long axis of the crystal or perpendicular to the plane of the crystal, respectively. This arrangement neutralizes the polarization of reflection as a result of the different interfacial Brewster's angles of each population. The fish reflective mechanism is distinct from existing non-polarizing mirror designs4,5,6,7 in that, importantly, there is no refractive index contrast between the low-index layers in the reflector and the external environment. This mechanism could be readily manufactured and exploited in synthetic optical devices.
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Acknowledgements
The authors acknowledge support from the Biotechnology and Biological Sciences Research Council (NWR – grant no. BB/G022917/1 and BB/H01635X/1), the Engineering and Physical Sciences Research Council (TMJ – grant no. EP/E501214/1) and the Air Force Office of Scientific Research (NWR – grant no. FA-9550-09-1-0149). The authors thank J. McGregor and S.E. Temple for valuable discussions and I.C. Cuthill for advice on statistical analyses.
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J.C.P. initiated the study. T.M.J and N.W.R. performed the modelling and experiments. All authors interpreted the data and co-authored the paper.
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Jordan, T., Partridge, J. & Roberts, N. Non-polarizing broadband multilayer reflectors in fish. Nature Photon 6, 759–763 (2012). https://doi.org/10.1038/nphoton.2012.260
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DOI: https://doi.org/10.1038/nphoton.2012.260
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