Intensity fluctuations signature of 3D Anderson localization of light

Apart from the difficulty of producing highly scattering samples, a major challenge in the observation of Anderson localization of 3D light is identifying an unambiguous signature of the phase transition in experimentally feasible situations. In this letter we establish a clear correspondence between the collapse of the conductance, the increase in intensity fluctuations at the localization transition and the scaling analysis results based on the Thouless number, thus connecting the macroscopic and microscopic approaches of localization. Furthermore, the transition thus inferred is fully compatible both with the results based on the eigenvalue analysis of the microscopic description and with the effective-medium Ioffe-Regel criterion

Role of disorder in super- and subradiance of cold atomic clouds

The presence of superradiance and subradiance in microscopic and mean-field approaches to light scattering in atomic media is investigated. We show that these phenomena are present in both descriptions, with only minor quantitative differences, so neither rely on disorder. In particular, they are most prominent in media with high resonant optical depth yet far-detuned light, i.e.. in the single--scattering regime

Microbial exposure during early human development primes fetal immune cells

Human fetal immune system begins to develop early during gestation, however factors responsible for fetal immune-priming remain elusive. We explored potential exposure to microbial agents in-utero and their contribution towards activation of memory T cells in fetal tissues. We profiled microbes across fetal organs using 16S-rRNA gene sequencing and detected low but consistent microbial signal in fetal gut, skin, placenta and lungs, in 2nd trimester of gestation. We identified several live bacterial strains including Staphylococcus and Lactobacillus in fetal tissues, which induced in vitro activation of memory T cells in fetal mesenteric lymph-node, supporting the role of microbial exposure in fetal immune-priming. Finally, using SEM and RNA-ISH, we visualised discrete localisation of bacteria-like structures and eubacterial-RNA within 14th week fetal gut lumen. These findings indicate selective presence of live-microbes in fetal organs during 2nd trimester of gestation and have broader implications towards establishment of immune competency and priming before birt

Interaction lumière-atomes : approche de champ moyen et fluctuations d’intensité

In this thesis, we investigate the coherent scattering of light propagating in a random medium. We are interested in phenomena like the super- and subradiance and Anderson localization that are related to waves interferences and spatial disorder. However, the fundamental difference between subradiance and Anderson localization still needs to be clarified. This thesis gives new elements for the understanding of these phenomena and we present a new method to observe Anderson localization. A mean-field model that does not contain disorder is developed, and we show that super- and subradiance do not require disorder whereas Anderson localization does. In this theoretical work, the coupling between the light and many atoms is reduced to a coupling matrix between the atoms by tracing over the degrees of freedom of the light, which results in a linear problem for the atomic dipoles. The study of the eigenvalues and eigenmodes of this matrix then allows to determine the super- and subradiant modes, and to probe the Anderson localization phase transition with a scaling analysis. Furthermore, the link to the experiment is realized by showing that the intensity fluctuations present an increase at the localization transition. The system is studied in the steady-state regime when the medium is continuously charged by a laser until reaches a stationary regime, and the decay dynamics, when the laser is switched off, so the cloud releases the energy stored. Finally, we present a preliminary work that shows that the diagonal disorder might be a good strategy to reach Anderson localization.Dans cette thèse, nous étudions la diffusion cohérente de la lumière se propageant dans un milieu désordonné. Nous nous intéressons à des phénomènes tels que la super- et sousradiance et la localisation d’Anderson qui sont liées aux interférences et au désordre spatial. Cependant, la différence fondamentale entre la sousradiance et la localisation d'Anderson doit encore être clarifiée. Cette thèse donne de nouvelles idées pour la compréhension de ces phénomènes et nous présentons une nouvelle méthode pour observer la localisation d'Anderson. On développe un modèle à champ moyen qui ne contient pas de désordre, et nous montrons que super- et sousradiance ne nécessitent pas de désordre contrairement à la localisation d’Anderson. Dans ce travail théorique, le couplage entre la lumière et les atomes est réduit à une matrice de couplage entre les atomes en calculant la trace sur les degrés de liberté de la lumière, ce qui nous amène à un problème linéaire pour les dipôles atomiques. L'étude des valeurs propres et des modes propres de cette matrice permet de déterminer des modes super- et sousradiant, et de sonder la transition de phase de localisation avec une scaling analysis. De plus, le lien avec l'expérience est fait en montrant que les fluctuations de l’intensité augmentent à travers la transition de localisation. Le système est étudié en régime stationnaire, quand le milieu est continûment chargé par un laser et que celui-ci atteint l’équilibre, et en dynamique, quand le laser est éteint et que le milieu se décharge de l’énergie stockée. Enfin, nous présentons un travail préliminaire qui montre que le désordre diagonal peut être une bonne stratégie pour atteindre la localisation d’Anderson

Light-atom interaction : mean-field approach and intensity fluctuations

Dans cette thèse, nous étudions la diffusion cohérente de la lumière se propageant dans un milieu désordonné. Nous nous intéressons à des phénomènes tels que la super- et sousradiance et la localisation d’Anderson qui sont liées aux interférences et au désordre spatial. Cependant, la différence fondamentale entre la sousradiance et la localisation d'Anderson doit encore être clarifiée. Cette thèse donne de nouvelles idées pour la compréhension de ces phénomènes et nous présentons une nouvelle méthode pour observer la localisation d'Anderson. On développe un modèle à champ moyen qui ne contient pas de désordre, et nous montrons que super- et sousradiance ne nécessitent pas de désordre contrairement à la localisation d’Anderson. Dans ce travail théorique, le couplage entre la lumière et les atomes est réduit à une matrice de couplage entre les atomes en calculant la trace sur les degrés de liberté de la lumière, ce qui nous amène à un problème linéaire pour les dipôles atomiques. L'étude des valeurs propres et des modes propres de cette matrice permet de déterminer des modes super- et sousradiant, et de sonder la transition de phase de localisation avec une scaling analysis. De plus, le lien avec l'expérience est fait en montrant que les fluctuations de l’intensité augmentent à travers la transition de localisation. Le système est étudié en régime stationnaire, quand le milieu est continûment chargé par un laser et que celui-ci atteint l’équilibre, et en dynamique, quand le laser est éteint et que le milieu se décharge de l’énergie stockée. Enfin, nous présentons un travail préliminaire qui montre que le désordre diagonal peut être une bonne stratégie pour atteindre la localisation d’Anderson.In this thesis, we investigate the coherent scattering of light propagating in a random medium. We are interested in phenomena like the super- and subradiance and Anderson localization that are related to waves interferences and spatial disorder. However, the fundamental difference between subradiance and Anderson localization still needs to be clarified. This thesis gives new elements for the understanding of these phenomena and we present a new method to observe Anderson localization. A mean-field model that does not contain disorder is developed, and we show that super- and subradiance do not require disorder whereas Anderson localization does. In this theoretical work, the coupling between the light and many atoms is reduced to a coupling matrix between the atoms by tracing over the degrees of freedom of the light, which results in a linear problem for the atomic dipoles. The study of the eigenvalues and eigenmodes of this matrix then allows to determine the super- and subradiant modes, and to probe the Anderson localization phase transition with a scaling analysis. Furthermore, the link to the experiment is realized by showing that the intensity fluctuations present an increase at the localization transition. The system is studied in the steady-state regime when the medium is continuously charged by a laser until reaches a stationary regime, and the decay dynamics, when the laser is switched off, so the cloud releases the energy stored. Finally, we present a preliminary work that shows that the diagonal disorder might be a good strategy to reach Anderson localization

Interação luz-átomo: abordagem de campo médio e flutuações de intensidade

In this thesis, we investigate the coherent scattering of light propagating in a random medium. We are interested in phenomena like the super- and subradiance and Anderson localization that are related to waves interferences and spatial disorder. However, the fundamental difference between subradiance and Anderson localization still needs to be clarified. This thesis gives new elements for the understanding of these phenomena and we present a new method to observe Anderson localization. A mean-field model that does not contain disorder is developed, and we show that super- and subradiance do not require disorder whereas Anderson localization does. In this theoretical work, the coupling between the light and many atoms is reduced to a coupling matrix between the atoms by tracing over the degrees of freedom of the light, which results in a linear problem for the atomic dipoles. The study of the eigenvalues and eigenmodes of this matrix then allows to determine the super- and subradiant modes, and to probe the Anderson localization phase transition with a scaling analysis. Furthermore, the link to the experiment is realized by showing that the intensity fluctuations present an increase at the localization transition. The system is studied in the steady-state regime when the medium is continuously charged by a laser until reaches a stationary regime, and the decay dynamics, when the laser is switched off, so the cloud releases the energy stored. Finally, we present a preliminary work that shows that the diagonal disorder might be a good strategy to reach Anderson localization.Nesta tese, investigamos o espalhamento coerente de luz propagando em um meio aleatório. Estamos interessados em fenômenos como superradiância, subradiância e localização de Anderson, os quais estão relacionados com interferências de ondas e desordem espacial. No entanto, as diferenças fundamentais entre subradiância e localização de Anderson ainda precisam ser esclarecidas. Esta tese traz novos elementos na compreensão destes fenômenos e apresentamos um novo método para observar a localização de Anderson. Neste trabalho teórico, estudamos os autovalores e os automodos de uma matriz de acoplamento que permite extrair modos super- e subradiantes, e exibem uma transição de fase de localização de Anderson através de uma análise de escalamento. Além disso, a conexão com o experimento é feita através da intensidade irradiada pela nuvem em todas as direções. Distinguimos dois casos: o regime de estado estacionário, quando o meio é continuamente excitado por um laser e alcança um regime estacionário; e o caso dinâmico, onde o laser é desligado e a nuvem libera a energia armazenada. Desenvolvemos um modelo de campo médio que não inclui desordem, e mostramos que super- e subradiância não precisam da desordem para existir, ao contrário da localização de Anderson. Mostramos também que podemos observar uma transição de fase de localização de Anderson na estatística da intensidade. Finalmente, apresentamos um trabalho preliminar que mostra que a desordem diagonal pode ser uma boa estratégia para alcançar a localização de Anderson

Interação luz-átomo: abordagem de campo médio e flutuações de intensidade

In this thesis, we investigate the coherent scattering of light propagating in a random medium. We are interested in phenomena like the super- and subradiance and Anderson localization that are related to waves interferences and spatial disorder. However, the fundamental difference between subradiance and Anderson localization still needs to be clarified. This thesis gives new elements for the understanding of these phenomena and we present a new method to observe Anderson localization. A mean-field model that does not contain disorder is developed, and we show that super- and subradiance do not require disorder whereas Anderson localization does. In this theoretical work, the coupling between the light and many atoms is reduced to a coupling matrix between the atoms by tracing over the degrees of freedom of the light, which results in a linear problem for the atomic dipoles. The study of the eigenvalues and eigenmodes of this matrix then allows to determine the super- and subradiant modes, and to probe the Anderson localization phase transition with a scaling analysis. Furthermore, the link to the experiment is realized by showing that the intensity fluctuations present an increase at the localization transition. The system is studied in the steady-state regime when the medium is continuously charged by a laser until reaches a stationary regime, and the decay dynamics, when the laser is switched off, so the cloud releases the energy stored. Finally, we present a preliminary work that shows that the diagonal disorder might be a good strategy to reach Anderson localization.Nesta tese, investigamos o espalhamento coerente de luz propagando em um meio aleatório. Estamos interessados em fenômenos como superradiância, subradiância e localização de Anderson, os quais estão relacionados com interferências de ondas e desordem espacial. No entanto, as diferenças fundamentais entre subradiância e localização de Anderson ainda precisam ser esclarecidas. Esta tese traz novos elementos na compreensão destes fenômenos e apresentamos um novo método para observar a localização de Anderson. Neste trabalho teórico, estudamos os autovalores e os automodos de uma matriz de acoplamento que permite extrair modos super- e subradiantes, e exibem uma transição de fase de localização de Anderson através de uma análise de escalamento. Além disso, a conexão com o experimento é feita através da intensidade irradiada pela nuvem em todas as direções. Distinguimos dois casos: o regime de estado estacionário, quando o meio é continuamente excitado por um laser e alcança um regime estacionário; e o caso dinâmico, onde o laser é desligado e a nuvem libera a energia armazenada. Desenvolvemos um modelo de campo médio que não inclui desordem, e mostramos que super- e subradiância não precisam da desordem para existir, ao contrário da localização de Anderson. Mostramos também que podemos observar uma transição de fase de localização de Anderson na estatística da intensidade. Finalmente, apresentamos um trabalho preliminar que mostra que a desordem diagonal pode ser uma boa estratégia para alcançar a localização de Anderson

Microbial exposure during early human development primes fetal immune cells

10.1016/j.cell.2021.04.039Cell1841