Optical Studies ofNano-Structures in the Beetle<em>Cetonia Aurata</em><em></em>

Shamim, Rizwana

January 2009

<p> </p><p> </p><p> </p><p><p>The main</p><p>objective of this thesis is to study the polarization effects of the beetle <em>Cetonia aurata </em>using Mueller-matrix ellipsometry. The outer shell of the beetle consists of complex microstructures which control the polarization of the reflected light. It has metallic appearance which originates from helicoidal structures. When these microstructures are exposed to polarized or unpolarized light, only left-handed circularly polarized light is reflected. Moreover, the exo-skeleton of the beetle absorbs right-handed polarized light. Multichannel Mueller-matrix ellipsometer or dual rotating compensator ellipsometer, called RC2, from J.A.Woollam is used to measure the polarization caused by different parts of beetle’s body. The 16 Mueller matrix elements are measured in the spectral range 400-800 nm at multiple angles of incidencein the range 40⁰-70⁰. An Optical model is developed to help us understand the nature and type of microstructure which only reflects the green colour circularly polarized light. With the help of multiparametric modeling, we were able to find optical properties and structural parameters. The parameters are: the number of layers, the numbers of sub-layers, their thicknesses, and the orientation with respect to optical axes. This optical model describes the nanostructures which provide the reflection properties similar to the nanostructure found in the beetle <em>Cetonia aurata. </em>The model is also useful for analysis of the optical response data of different materials with multilayer structures.</p></p><p> </p>

Cetonia aurata

Mueller-matrix ellipsometry

Helicoidal structures

Left-handed circularly polarized light

Physics

Fysik

Optical Studies ofNano-Structures in the BeetleCetonia Aurata

Shamim, Rizwana

January 2009

The main objective of this thesis is to study the polarization effects of the beetle Cetonia aurata using Mueller-matrix ellipsometry. The outer shell of the beetle consists of complex microstructures which control the polarization of the reflected light. It has metallic appearance which originates from helicoidal structures. When these microstructures are exposed to polarized or unpolarized light, only left-handed circularly polarized light is reflected. Moreover, the exo-skeleton of the beetle absorbs right-handed polarized light. Multichannel Mueller-matrix ellipsometer or dual rotating compensator ellipsometer, called RC2, from J.A.Woollam is used to measure the polarization caused by different parts of beetle’s body. The 16 Mueller matrix elements are measured in the spectral range 400-800 nm at multiple angles of incidencein the range 400-700. An Optical model is developed to help us understand the nature and type of microstructure which only reflects the green colour circularly polarized light. With the help of multiparametric modeling, we were able to find optical properties and structural parameters. The parameters are: the number of layers, the numbers of sub-layers, their thicknesses, and the orientation with respect to optical axes. This optical model describes the nanostructures which provide the reflection properties similar to the nanostructure found in the beetle Cetonia aurata. The model is also useful for analysis of the optical response data of different materials with multilayer structures.

Cetonia aurata

Mueller-matrix ellipsometry

Helicoidal structures

Left-handed circularly polarized light

Physics

Fysik

Dichroïsme Circulaire de Photoélectrons (PECD) sur des systèmes chiraux isolés / Photoelectron Circular Dichroism (PECD) on isolated chiral systems

Tia, Maurice

19 November 2014

Le dichroïsme circulaire de photoélectrons (PECD) se manifeste par une intense asymétrie avant/arrière dans la distribution angulaire de photoélectrons selon l’axe des photons, lors de la photoionisation d’un énantiomère pur de molécule chirale en phase gazeuse par un rayonnement polarisé circulairement. Cette thèse est consacrée à l’étude de ce phénomène, avec le synchrotron de la ligne DESIRS, sur différents systèmes chiraux allant de molécules libres (composés bromés, alanine) aux agrégats de glycidol et aux complexes formés avec l’eau. Pour ce faire, des mesures expérimentales menées à l’aide du spectromètre double imageur à coïncidence électron/ion DELICIOUS 3 ont été couplées à des calculs théoriques (CMS-Xα). Le chapitre 1 introduit les concepts fondamentaux nécessaires à l’étude de la chiralité en physique et le chapitre 2 présente les méthodes expérimentales et théoriques mises en œuvre. Le chapitre 3 détaille les résultats obtenus sur des composés chiraux halogénés : l’acide bromo-propionique (BPA) et les isomères 1,3- et 1,4-bromo-phényléthylamine (BrPhEtA). La sensibilité du PECD à l’isomérie, de même que le rôle de la localisation de l’orbitale initiale par rapport au centre chiral sont au cœur de cette étude. Le PECD du plus simple acide aminé chiral protéique, l’alanine, produit par chauffage résistif et par thermo-désorption d’aérosol, est présenté au chapitre 4 avec une étude conformationnelle selon la température conduisant à une distribution plausible des conformères. Ces résultats sont ensuite discutés dans le contexte de l’homochiralité de la vie (i.e. le fait que les acides aminés sont tous de type L dans la biosphère), le PECD étant un processus photophysique asymétrique pouvant induire un enrichissement énantiomérique. Le chapitre 5 s’intéresse au PECD sur des systèmes plus complexes : les agrégats de glycidol et les complexes de glycidol et d’eau. Une simple sélection en masse permet de mettre en évidence un effet spectaculaire de l’agrégation sur le PECD observé. DELICIOUS 3 permet ensuite d’éliminer des processus en cascade par une sélection en taille des neutres natifs. / Photoelectron Circular Dichroism (PECD) is observed as a forward/backward asymmetry, with respect to the photon axis, of the photoelectron angular distributions resulting from the circularly polarized light-induced photoionization of gas phase pure enantiomers of chiral species. This thesis is devoted to the study, with the synchrotron of the DESIRS beamline, of this phenomenon on different chiral systems from free molecules (bromine compounds, alanine) to glycidol clusters and water-glycidol complexes. Chapter 1 introduces the fundamental concepts required for the study of chirality in physics and chapter 2 presents the experimental and theoretical methods which have been used. Chapter 3 gives details concerning the results on the halogenated chiral compounds: bromopropionic acid (BPA) and 1,3- and 1,4-bromo-phenylethylamine isomers (BrPhEtA). The sensitivity of PECD to isomerism as well as the role of the localization of the initial orbital of the outgoing electron with respect to the chiral center is at the core of this study. The PECD of the simplest proteic chiral amino acid, alanine, produced by resistive heating and thermodesorption of an aerosol, is introduced in chapter 4 with a conformational study depending on temperature, leading to a plausible conformer distribution. These results are then discussed in the context of homochirality of life (i.e. the fact that only L-amino acids are found in the biosphere) as PECD is an asymmetric photophysical processes which can induce an enantiomeric enrichment. Chapter 5 is focused on PECD in systems of greater complexity: glycidol clusters and water-glycidol complexes. A simple mass selection enables to unravel a spectacular clustering effect on the observed PECD and the use of DELICIOUS 3 enables then to remove any cascading processes thanks to a size selection of nascent species.

Chiralité

Asymétrie

Photoionisation

Lumière polarisée circulairement

Synchrotron

Phase gazeuse

Homochiralité

Molécules

Agrégats

Complexes

Photoelectron circular dichroism

Chirality

Asymmetry

Photoionization

Circularly polarized light

Synchrotron

Gaz phase

Homochirality

Molecules

Clusters

Complexes