Photonic simulation method applied to the study of structural color in Myxomycetes

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We present a novel simulation method to investigate the multicolored effect of the Diachea leucopoda (Physarales order, Myxomycetes class), which is a microorganism that has a characteristic pointillistic iridescent appearance. It was shown that this appearance is of structural origin, and is produc...

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Autores principales: Dolinko, A., Skigin, D., Inchaussandague, M., Carmaran, C.
Formato: JOUR
Materias:
Biological materials
Fungi
Protozoa
Biological structures
Corrugated sheets
Degree of complexity
Electromagnetic response
Geometrical shapes
Inhomogeneities
Interference effects
Protective layers
Simulation methods
Structural color
Structural origin
Transparent material
Color
article
computer simulation
cytology
methodology
Myxogastria
optics
photon
physiology
pigmentation
ultrastructure
Computer Simulation
Myxomycetes
Optics and Photonics
Photons
Pigmentation
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_10944087_v20_n14_p15139_Dolinko
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_10944087_v20_n14_p15139_Dolinko
record_format dspace
spelling todo:paper_10944087_v20_n14_p15139_Dolinko2023-10-03T16:05:12Z Photonic simulation method applied to the study of structural color in Myxomycetes Dolinko, A. Skigin, D. Inchaussandague, M. Carmaran, C. Biological materials Fungi Protozoa Biological structures Corrugated sheets Degree of complexity Electromagnetic response Geometrical shapes Inhomogeneities Interference effects Protective layers Simulation methods Structural color Structural origin Transparent material Color article computer simulation cytology methodology Myxogastria optics photon physiology pigmentation ultrastructure Computer Simulation Myxomycetes Optics and Photonics Photons Pigmentation We present a novel simulation method to investigate the multicolored effect of the Diachea leucopoda (Physarales order, Myxomycetes class), which is a microorganism that has a characteristic pointillistic iridescent appearance. It was shown that this appearance is of structural origin, and is produced within the peridium -protective layer that encloses the mass of spores-, which is basically a corrugated sheet of a transparent material. The main characteristics of the observed color were explained in terms of interference effects using a simple model of homogeneous planar slab. In this paper we apply a novel simulation method to investigate the electromagnetic response of such structure in more detail, i.e., taking into account the inhomogeneities of the biological material within the peridium and its curvature. We show that both features, which could not be considered within the simplified model, affect the observed color. The proposed method is of great potential for the study of biological structures, which present a high degree of complexity in the geometrical shapes as well as in the materials involved. © 2012 Optical Society of America. Fil:Skigin, D. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Inchaussandague, M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Carmaran, C. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_10944087_v20_n14_p15139_Dolinko
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Biological materials
Fungi
Protozoa
Biological structures
Corrugated sheets
Degree of complexity
Electromagnetic response
Geometrical shapes
Inhomogeneities
Interference effects
Protective layers
Simulation methods
Structural color
Structural origin
Transparent material
Color
article
computer simulation
cytology
methodology
Myxogastria
optics
photon
physiology
pigmentation
ultrastructure
Computer Simulation
Myxomycetes
Optics and Photonics
Photons
Pigmentation
spellingShingle Biological materials
Fungi
Protozoa
Biological structures
Corrugated sheets
Degree of complexity
Electromagnetic response
Geometrical shapes
Inhomogeneities
Interference effects
Protective layers
Simulation methods
Structural color
Structural origin
Transparent material
Color
article
computer simulation
cytology
methodology
Myxogastria
optics
photon
physiology
pigmentation
ultrastructure
Computer Simulation
Myxomycetes
Optics and Photonics
Photons
Pigmentation
Dolinko, A.
Skigin, D.
Inchaussandague, M.
Carmaran, C.
Photonic simulation method applied to the study of structural color in Myxomycetes
topic_facet Biological materials
Fungi
Protozoa
Biological structures
Corrugated sheets
Degree of complexity
Electromagnetic response
Geometrical shapes
Inhomogeneities
Interference effects
Protective layers
Simulation methods
Structural color
Structural origin
Transparent material
Color
article
computer simulation
cytology
methodology
Myxogastria
optics
photon
physiology
pigmentation
ultrastructure
Computer Simulation
Myxomycetes
Optics and Photonics
Photons
Pigmentation
description We present a novel simulation method to investigate the multicolored effect of the Diachea leucopoda (Physarales order, Myxomycetes class), which is a microorganism that has a characteristic pointillistic iridescent appearance. It was shown that this appearance is of structural origin, and is produced within the peridium -protective layer that encloses the mass of spores-, which is basically a corrugated sheet of a transparent material. The main characteristics of the observed color were explained in terms of interference effects using a simple model of homogeneous planar slab. In this paper we apply a novel simulation method to investigate the electromagnetic response of such structure in more detail, i.e., taking into account the inhomogeneities of the biological material within the peridium and its curvature. We show that both features, which could not be considered within the simplified model, affect the observed color. The proposed method is of great potential for the study of biological structures, which present a high degree of complexity in the geometrical shapes as well as in the materials involved. © 2012 Optical Society of America.
format JOUR
author Dolinko, A.
Skigin, D.
Inchaussandague, M.
Carmaran, C.
author_facet Dolinko, A.
Skigin, D.
Inchaussandague, M.
Carmaran, C.
author_sort Dolinko, A.
title Photonic simulation method applied to the study of structural color in Myxomycetes
title_short Photonic simulation method applied to the study of structural color in Myxomycetes
title_full Photonic simulation method applied to the study of structural color in Myxomycetes
title_fullStr Photonic simulation method applied to the study of structural color in Myxomycetes
title_full_unstemmed Photonic simulation method applied to the study of structural color in Myxomycetes
title_sort photonic simulation method applied to the study of structural color in myxomycetes
url http://hdl.handle.net/20.500.12110/paper_10944087_v20_n14_p15139_Dolinko
work_keys_str_mv AT dolinkoa photonicsimulationmethodappliedtothestudyofstructuralcolorinmyxomycetes
AT skigind photonicsimulationmethodappliedtothestudyofstructuralcolorinmyxomycetes
AT inchaussandaguem photonicsimulationmethodappliedtothestudyofstructuralcolorinmyxomycetes
AT carmaranc photonicsimulationmethodappliedtothestudyofstructuralcolorinmyxomycetes
_version_ 1807320337938907136

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