High-Bitrate Photodetection in Ultraviolet-to-Visible for Optical Wireless Communication

Kang, Chun Hong

11 1900

Optical wireless communication, taking advantage of the unlicensed ultraviolet-to visible wavelength region of the electromagnetic spectrum, had been coined as the next-generation wireless communication technology and holds promises to deliver a high-speed, reliable, and secured broadband experience. The push towards the optical-based medium is manifested by the demand for additional channel bandwidth to accommodate the rapid growth of the Internet-of-Things (IoT) and Internet-of-Underwater-Things (IoUT). Therefore, high-bitrate optoelectronics devices and components forming the transceiver units used in an optical wireless communication system require substantial progression to accelerate the development of this paradigm-shifting technology. In this dissertation, we demonstrated a plethora of optical detection platforms to circumvent the existing long-standing issues related to modulation bandwidth, wavelength-selectiveness, and solar-blind ultraviolet-C detection found in conventional planar silicon-based optical detectors. Herein, we presented the semipolar group-III-nitride-based micro-photodiodes for enabling up to Gbit/s optical detection in the ultraviolet-to-violet domain. The wavelength-selectiveness nature of the micro-photodiodes enabled a bitrate of up to 1.5 Gbit/s based on a power-saving on-off-keying modulation scheme. While it offers a high bitrate for the optical communication link, it restricts its detection size and angle-of-view due to the conventional resistance-capacitance and étendue limits. Therefore, we also explored using polymer-based scintillating fibers as a high-speed and near-omnidirectional optical detection platform to cater to various dynamic scenarios in optical wireless communication. The detection platform formed by the scintillating fibers enabled near-omnidirectional and large-area optical detection without sacrificing the modulation bandwidth. These investigations paved the way towards relieving the resistance-capacitance limit while addressing the pointing, acquisition, and tracking issue in underwater wireless optical communication. Subsequently, we also presented a novel wavelength-converting mechanism based on halide-perovskite nanocrystals and a conventional silicon-based platform. This demonstration addressed the lack of ultraviolet-C optical detectors in the existing market and enabled future solar-blind optical communication links. Finally, we also presented on halide-perovskite polymer-based scintillating fibers as the high-bitrate and near-omnidirectional optical detection platform. Our studies successfully addressed the existing inadequacy for high-bitrate photodetection. These works could play a significant role in progressing the technology forward, based on bottom-up material and devices innovation, to offer a reliable internet connection to the future highly interconnected society.

Photodetectors

Optical wireless communication

Perovskite

Optoelectronics

Scintillating fibers

Innovative Scintillating Optical Fibers For Detecting/Monitoring Gamma Radiation

Jayaprakash, Ashwini

09 December 2006

A scintillating optical fiber sensor of this work consists of a scintillating optical fiber, connected to a photomultiplier tube (PMT) via a conventional silica optical fiber. When a gamma ray impinges on the scintillating optical fiber, photons are generated inside the fiber. The photons are trapped inside the fiber and guided through the PMT. The PMT output signal is acquired by a computer. Two types of scintillating optical fibers sensors were developed for gamma ray detection. The first one is a silica optical fiber doped with an inorganic scintillating agent. The second one is a liquid core waveguide optical fiber filled with a solution of a nanostructured core shell CdSe/ZnS quantum dot. Test results indicate that the scintillating optical fibers developed in this work are sensitive for detecting gamma radiation. These scintillating fibers offer more flexibility for applications in nuclear energy industry as well as in nuclear medical research.

scintillating fiber

gamma radiation

sol-gel

quantum dot

scintillator

Development and study of luminescent bolometers for neutrino physics

Gimbal-Zofka, Yann

January 2017

This Master thesis aims at designing, assembling and operating a prototypal luminescentbolometer containing a candidate with high Q-value (116Cd and 100Mo)for the study of the neutrinoless double- decay. The crystal is scintillating (with 116CdWO4 and Li2MoO4 compounds). The prototype is designed according to a simple thermal model and cooled down to 18 mK. Data analysis of the 116CdWO4 crystal determines the energy resolution (intrinsicand in the ROI) and the alpha/beta discrimination power. It includes a full interpretation of the background energy spectrum in terms of environmental radioactivity and an evaluation of the crystal radiopurity by the detection of internal contamination of the detector. An evaluation of the potential of a future experiment based on the 116CdWO4developed prototype is performed, ascertaining the feasibility of large scale experiments to search for neutrinoless double beta decay. The use of the thermal model of the detector response to interpret its bolometric behaviour and the study of future optimizations of the detector performance concludes this project.

Neutrinoless double beta decay

bolometer

scintillating bolometer

leptogenesis

neutrino

cryostat

radioactivity

Development of cryogenic low background detector based on enriched zinc molybdate crystal scintillators to search for neutrinoless double beta decay of ¹⁰⁰Mo / Développement de détecteurs cryogéniques à faible bruit de fond composés de cristaus scintillateurs enrichis en molybdate de zinc pour la recherch de la double désintégration beta sans neutrinos du ¹⁰⁰Mo

Chernyak, Dmitry

08 July 2015

L’observation de la double désintégration bêta sans neutrinos (0ν2β) impliquerait la violation de la conservation du numéro leptonique, signe d’une nouvelle physique au-delà du Modèle Standard, et permettrait d’établir la nature de Majorana des neutrinos. Les bolomètres scintillants cryogéniques sont parmi les détecteurs les plus prometteurs pour rechercher ce processus nucléaire extrêmement rare dans des noyaux qui sont théoriquement entre les plus favorables.Des scintillateurs de ZnMoO₄ ayant une masse de ∼ 0.3 kg, ainsi que des cristaux de Zn¹⁰⁰ MoO₄ enrichi dans l’isotope ¹⁰⁰Mo, ont été produits pour la première fois en utilisant la technique de Czochralski à faible gradient thermique. Les propriétés optiques et de luminescence des cristaux produits ont été étudiées pour évaluer le progrès de la qualité de la croissance des cristaux. Des tests à basse température avec un scintillateur de 313 g de ZnMoO₄et deux scintillateurs de Zn¹⁰⁰ MoO₄ enrichis ont été réalisées en surface au Centre de Sciences Nucléaires et de Sciences de la Matière. On a aussi mené des mesures à faible fond radioactif avec trois cristaux de ZnMoO₄ naturels et deux détecteurs enrichis, installés dans le setup d’ EDELWEISS au Laboratoire Souterrain de Modane.Pour optimiser la collecte de la lumière dans des bolomètres scintillants cryogénique de ZnMoO₄, nous avons simulé par une méthode Monte Carlo la collecte des photons de scintillation dans un module de détection pour différentes géométries, en utilisant le logiciel GEANT4. La réponse à la désintégration 2ν2β de ¹⁰⁰Mo a été simulée pour des détecteurs enrichis de Zn¹⁰⁰ MoO₄ avec forme et masse différente, avec le but de comprendre la structure des spectres 2ν2β en fonctionne de la forme des cristaux. Nous avons simulé aussi la performance de 48 cristaux de Zn¹⁰⁰ MoO₄ ayant une taille de Ø60 × 40 mm et installés dans le cryostat d’EDELWEISS. La contribution au fond de la contamination radioactive interne des cristaux, l’activation cosmogénique et la contamination radioactive du setup ont été simulées.Tenant compte de la modeste résolution temporelle des bolomètres à basse température, nous avons également étudié la contribution au fond à l'énergie Q₂β déterminé par des coïncidences aléatoires de signaux, en particulier du à la décroissance 2ν2β, qui est l'une des sources de fond les plus dangereuses dans les bolomètres cryogéniques. Des méthodes pour le rejet d’événements coïncidant par hasard ont été développées et comparées. Nous avons également analysé la dépendance de l'efficacité de rejet à l’égard des performances du détecteur cryogénique. / Observation of neutrinoless double beta (0ν2β) decay would imply the violation of lepton number conservation and definitely new physics beyond the Standard Model, establishing the Majorana nature of neutrinos. Cryogenic scintillating bolometers look the most promising detectors to search for this extremely rare nuclear process in a few theoretically the most favorable nuclei.ZnMoO₄ scintillators with a mass of ∼ 0.3 kg, as well as Zn¹⁰⁰ MoO₄ crystals enriched in the isotope ¹⁰⁰Mo were produced for the first time by using the low-thermal-gradient Czochralski technique. The optical and luminescent properties of the produced crystals were studied to estimate the progress in crystal growth quality. The low-temperature tests with a 313 g ZnMoO₄ scintillator and two enriched Zn¹⁰⁰ MoO₄ were performed aboveground in the Centre de Sciences Nucléaires et de Sciences de la Matière. The low background measurements with a three ZnMoO₄ and two enriched detectors installed in the EDELWEISS set-up at the Laboratoire Souterrain de Modane were carried out.To optimize the light collection in ZnMoO₄ cryogenic scintillating bolometers, we have simulated the collection of scintillation photons in a detector module for different geometries by Monte Carlo method using the GEANT4 package. Response to the 2ν2β decay of ¹⁰⁰Mo was simulated for the enriched Zn¹⁰⁰ MoO₄ detectors of different shape and mass to understand the dependence of 2ν2β decay spectra on crystal shape. We have simulated 48 Zn¹⁰⁰ MoO₄ crystals with a size of Ø60 × 40 mm installed in the EDELWEISS cryostat. The contribution to background from the internal radioactive contamination of the crystals, cosmogenic activation and radioactive contamination of the set-up were simulated.Taking into account the poor time resolution of the low temperature bolometers, we also studied contribution to background at the Q₂β energy of random coincidences of signals, in particular of 2ν2β decay, which is one of the most valuable sources of background in cryogenic bolometers. Methods of the randomly coinciding events rejection were developed and compared. We have also analyzed dependence of the rejection efficiency on a cryogenic detector performance.

Double désintégration bêta

Scintillateurs

Bolomètres scintillants cryogéniques

Double beta decay

Scintillators

Cryogenic scintillating bolometers

Search for heavy Majorana neutrinos in pp collisions at √s = 8 TeV with the CMS detector & photodetector and calorimeter R&D for particle colliders.

Tiras, Emrah

01 January 2017

This thesis contains both physics analysis and hardware studies. It consists of two primary sections: the results of a search for heavy Majorana mass neutrinos, using the event signature of same (like) sign charged electron pairs ($e^{\pm} e^{\pm}$ ) and two jets, and the results of studies to upgrade the Hadronic Forward (HF) and Hadronic Endcap (HE) subdetectors in the Compact Muon Solenoid (CMS) detector in response to the high intensity proton-proton collisions generated at the Large Hadron Collider (LHC) at European Organization for Nuclear Research (CERN, Conseil Europ\'{e}en pour la Recherche Nucl\'{e}aire). In this search for Majorana mass neutrinos, same sign dielectron ($e^{\pm} e^{\pm}$) + dijet events in the final state have been considered as a signature for neutrino particles. The analyzed data corresponds to an integrated luminosity of 19.7 fb\textsuperscript{-1} of proton-proton collisions at a center of mass energy of \begin{math}\sqrt{s} = 8\ TeV \end{math}, collected using the CMS detector during the 2012 operation at the LHC. Monte Carlo simulations accounting for the theoretical expectations of the Standard Model (SM) and the detector limitations are used to prototype the experiment and to test proposed analysis steps. No excess of events is observed in the data beyond the expected SM background. Upper limits are set on the mixing element squared, $|{V}_{eN}|^{2}$, of the heavy Majorana neutrino with standard model neutrinos, as a function of Majorana neutrino mass for masses in the range of 40-500 $GeV/c^2$. The detector upgrade search comprises three sections of this thesis. The first section describes the test results of 1785 multianode Hamamatsu R7600U-200-M4 photomultiplier tubes (PMT) in numerous parameters such as gain, dark current, and timing characteristics, which provide insights on the expected performance of the upgraded CMS-HF detector. These PMTs replaced the previous single anode R7525 PMTs because the glass windows of previous PMTs are the source of Cherenkov radiation, which causes a background noise in the experiment. The second section reports characterization results of two types of PMTs in a novel operation mode for Secondary Emission (SE) Ionization Calorimetry, which is a novel technique to measure electromagnetic shower particles in extreme radiation environments. The third section presents the test results of novel scintillating materials for CMS experiment in specific and future particle accelerators in general. These materials are Polyethylene Naphthalate (PEN), Polyethylene Terephthalate (PET), high efficiency mirror (HEM) and quartz plates with various organic and inorganic coating materials such as p-Terphenyl (pTp), Anthracene and Gallium-doped Zinc Oxide (ZnO:Ga). We have investigated them for radiation hardness, light yield, timing characteristics, and scintillation and transmission properties.

Calorimeter

Majorana neutrino

Photodetector

Photomultiplier Tubes

Physics

Computational role of disinhibition in brain function

Yu, Yingwei

02 June 2009

Neurons are connected to form functional networks in the brain. When neurons are combined in sequence, nontrivial effects arise. One example is disinhibition; that is, inhibition to another inhibitory factor. Disinhibition may be serving an important purpose because a large number of local circuits in the brain contain disinhibitory connections. However, their exact functional role is not well understood. The objective of this dissertation is to analyze the computational role of disinhibition in brain function, especially in visual perception and attentional control. My approach is to propose computational models of disinhibition and then map the model to the local circuits in the brain to explain psychological phenomena. Several computational models are proposed in this dissertation to account for disinhibition. (1) A static inverse difference of Gaussian filter (IDoG) is derived to account explicitly for the spatial effects of disinhibition. IDoG can explain a number of complex brightness-contrast illusions, such as the periphery problem in the Hermann grid and the White's effect. The IDoG model can also be used to explain orientation perception of multiple lines as in the modified version of Poggendorff illusion. (2) A spatio-temporal model (IDoGS) in early vision is derived and it successfully explains the scintillating grid illusion, which is a stationary display giving rise to a striking, dynamic, scintillating effect. (3) An interconnected Cohen-Grossberg neural network model (iCGNN) is proposed to address the dynamics of disinhibitory neural networks with a layered structure. I derive a set of sufficient conditions for such an interconnected system to reach asymptotic stability. (4) A computational model combining recurrent and feed-forward disinhibition is designed to account for input-modulation in temporal selective attention. The main contribution of this research is that it developed a unified framework of disinhibition to model several different kinds of neural circuits to account for various perceptual and attentional phenomena. Investigating the role of disinhibition in the brain can provide us with a deeper understanding of how the brain can give rise to intelligent and complex functions.

disinhibition

visual perception

cognitive modeling

scintillating grid

poggendorff illusion

Stroop effect

Prototyp detektoru reaktorových antineutrin / Prototyp detektoru reaktorových antineutrin

Fajt, Lukáš

January 2015

Title: Prototype of detector for detection of reactor's antineutrinos Author: Lukáš Fajt Department: Institute of Particle and Nuclear Physics Supervisor: Doc. Ing. Ivan Štekl, CSc., IEAP, CTU in Prague Abstract: This master thesis is related to the development of the complex detector of reac- tor's antineutrinos, so called S3 , which is based on the polystyrene scintillation detectors. The detector S3 (dimensions 40 x 40 x 40 cm3 ) will be located in the close vicinity of a nuclear reactor (5-12 m) and its purpose will be to measure reactor's power, isotopic composition of the nuclear fuel and moreover verification of the sterile neutrino hypothesis by detecting reactor's antineutrinos via the Inverse Beta Decay (IBD) interaction. Within the thesis, the first prototype of the antineutrino detector was constructed. It is composed of 18 scintillation plates (40 x 20 x 1 cm3 ) and corresponding electronics. With this prototype the first test with cosmic muons were performed. Within the thesis, the energy reso- lution of the scintillation plates was significantly improved by the optimization of their chemical composition and selection of the optimal refractive material. The proper energy resolution is very important for the detector functionality. In addition, a new methods for the production of coating layer...

Étude et développement d'un imageur TEP ambulatoire pour le suivi thérapeutique individualisé en cancérologie / Study and development of a PET device dedicated to cancer monitoring

Vandenbussche, Vincent

30 September 2014

L'imagerie médicale remonte à la fin du XIXe siècle avec la découverte des rayons X par Röntgen. Depuis, de nombreuses modalités d'imagerie ont été développées, et sont aujourd'hui utilisées dans une large gamme d'indications cliniques. L'imagerie TEP (Tomographie par Émission de Positron) est une modalité fonctionnelle, quantitative et ayant une haute sensibilité, ce qui en fait une modalité de choix, notamment en cancérologie. Hélas, sa diffusion est freinée en comparaison avec le scanner ou l'imagerie par résonance magnétique, en raison de son coût notamment. C'est dans ce contexte que s'insère cette thèse, qui a pour objectif de montrer la faisabilité d'un imageur TEP ambulatoire dédié au suivi thérapeutique en cancérologie. À partir de développements instrumentaux originaux (localisation des gammas par division de lumière dans des barreaux scintillateurs, lecture à l'aide de Silicon PhotoMultiplier, géométrie compacte), ces travaux s'efforcent de baisser les coûts tout en restant compétitif en terme de performances. Dans un premier temps, une étude extensive de la division de lumière à travers toute une série de paramètres (longueur des barreaux scintillateurs, revêtement optique, matériau scintillateur, traitement des données) a été menée. Une résolution spatiale inférieure à 5 mm pour un barreau de 75 mm de LYSO emballé dans du teflon a notamment été obtenue. À partir de cette configuration, une première image a été reconstruite, à partir de deux modules en coïncidence, offrant une résolution spatiale de 5 mm pour un tel imageur. Enfin, toute une série de simulations a été menée, à partir des données expérimentales et avec une géométrie originale. En particulier, les performances ont été mesurées à partir du protocole NEMA, un standard permettant de comparer les performances à travers la littérature. Une résolution spatiale intrinsèque de l'ordre de 4 mm a été obtenue, soit meilleure que le marché actuel. La sensibilité de l'ordre de 2.5 cps/kBq est revanche relativement basse par rapport à l'existant, mais s'explique par un champ de vue axial restreint. Enfin, le potentiel en terme de quantification a été adressé, et est comparable au marché actuel. / Medical imaging first began at the end of the XIXth century with the discover of X-rays by Röntgen. Then, numerous imaging modalities have been developed and are used now for a wide range of cases. Positron Emission Tomography (PET) has a high sensitivity, is functional and quantitative, thus being of high interest in cancer monitoring. Nevertheless, PET is not as much spread in hospitals as magnetic resonance imaging and scanner. In this context, this work aims to prove the faisability of PET dedicated for cancer monitoring. Thanks to instrumental developments such as light sharing in scintillating crystals, use of Silicon Photomultipliers, and an original geometry, cost is expected to be reduced while having same performances as commercial devices. An extensive study of light sharing within scintillating barrels has been made, through many parameters (crystal length, coating, data analysis...). An intrinsic spatial resolution of 4 mm has been measured over a 75 mm long crystal of LYSO, coated with teflon. From such a configuration, a first image has been reconstructed using two modules in coincidence. A spatial resolution of 5 mm has been measured in the image. Finally, Monte Carlo simulations has been made with experimental data as input, in order to measure the performances of the final PET device. Thanks to NEMA standard protocol, performances has been measured and compared to other systems. A spatial resolution of 4 mm has been reached, for a sensitivity of 2.5 cps/kBq. Quantification problem has been assessed, providing results similar to existing devices.

PET (Positron Emission Tomography)

Scintillateur

SiPM

GATE

Monte Carlo

PET (Positron Emission Tomography)

Scintillating crystal

SiPM

GATE

Monte Carlo

Measurement Of Sm Electro-weak Parameters In Reactor Antineutrino-electron Scattering In Texono Experiment

Deniz, Muhammed

01 May 2007

In this thesis a search for electron type neutrino-electron scattering cross-section and Weinberg Angle measurements were performed at KS Nuclear Power Station with 200 kg CsI(Tl) scintillating crystal detector located at a distance of 28 m from the 2.9 GW reactor core giving total flux of 6:52X10^12 cm^-2s^-1 in average at the experimental site. New analysis techniques and background suppression methods were developed. In the region of 3-8 MeV a measurement of SM cross section of (1:235+-0.577) XR_SM and Weinberg Angle of 0:264 +-0.075 which is quite consistent with the SM value of 0.23120(15)were obtained. These are the best results with wold wide level sensitivities at untested low energy region by using reactor anti-neutrinos.

Etude de la dosimétrie par scintillateur plastique pour l'irradiation préclinique du petit animal à moyenne énergie / Plastic scintillator dosimetry study for small animal preclinical irradiation at medium energy

Le deroff, Coralie

26 September 2017

Les micro-irradiateurs pour la radiothérapie préclinique du petit animal permettent d’effectuer des irradiations au plus proche des techniques de traitement chez l’homme, facilitant la transposition de résultats d'études radiobiologiques à la clinique. La spécificité des faisceaux millimétriques de moyenne énergie (< 300 keV) utilisés génère cependant des problématiques dosimétriques inédites. Ce travail de thèse a consisté à mettre en œuvre la dosimétrie par fibre scintillante plastique pour ce domaine d’utilisation, là où peu de détecteurs conviennent. Dans une première partie, les faisceaux d’un micro-irradiateur ont été caractérisés en dose d’une part et leur spectres en énergie obtenus par simulations Monte Carlo d’autre part, afin d’étudier les performances du dosimètre prototype. La deuxième partie a montré ses excellentes caractéristiques dosimétriques telles que la répétabilité, reproductibilité et linéarité de réponse. Un des enjeux majeurs a alors été de caractériser sa dépendance en énergie, problématique inhérente à la dosimétrie à moyenne énergie et intrinsèque au scintillateur plastique en dessous de 100 keV. Une méthode d’étalonnage a été proposée pour prendre en compte cette dépendance en conditions précliniques (mini-faisceaux et petit volume diffusant), à partir de spectres en énergie simulés. Le dosimètre a ensuite été utilisé pour la vérification de plans de traitement sur fantôme puis in vivo sur des rats, avec des résultats très concluants. Il a montré des performances prometteuses pour l’évaluation en temps réel de la dose délivrée aux tumeurs soumises aux mouvements respiratoires des animaux. / Small animal micro-irradiators designed for preclinical radiotherapy experiments mimic human clinical irradiation techniques thus facilitating the transposition of radiobiological research findings to clinical practice. These devices deliver millimetric x-ray beams of medium-energy (< 300 keV) which implies specific dosimetric issues. The objective of this thesis was the implementation of plastic scintillating fiber dosimetry in this specific field of use, for which few existing dosimeters are suitable. In a first part, beams from a micro-irradiator were characterized. Dosimetric measurements along with energy spectra Monte Carlo simulations allowed the study of the dosimeter prototype performances. In the second part of this work, excellent dosimetric properties of the detector such as repeatability, reproducibility and dose response linearity were shown. Then, a major issue was to determine the detector energy dependence, which is inherent to medium-energy dosimetry and also an intrinsic property of plastic scintillator, below 100 keV. A calibration method based on the simulated energy spectra was proposed to correct this dependence in preclinical conditions (mini-beams, small scattering volume). The dosimeter showed very conclusive results for treatment plan verification in a heterogene phantom and during rats in vivo experiments. The dosimeter also demonstrated promising performances for online control of the delivered dose to mobile tumors, subject to the animal respiratory movements.

Fibre scintillante

Quenching

Moyenne énergie

Radiothérapie préclinique

Modélisation Monte-Carlo

Mini-faisceaux

Preclinical radiotherapy

Dosimetry

Scintillating fiber

Quenching

Medium energy

Mini-beams

Monte Carlo