Etude de l'influence des plasmas dans les diodes à électrons pour la radiographie éclair / Study of the influence of plasma in electron diodes for flash radiography

Plewa, Jérémie-Marie

28 September 2018

La radiographie éclair par faisceau X intense est spécifique en ce sens qu'elle doit permettre de photographier la matière soumise à des conditions extrêmes de densification, de température et de vitesse de déplacement. Le succès de ce type de radiographie repose sur la qualité de la source X qui doit nécessairement être pénétrante (quelques MeV), intense (plusieurs rads), brève (quelques dizaines de ns) et de petite dimension (quelques mm). L'impulsion X est ainsi générée à partir du rayonnement de freinage émis lors de l'interaction avec une cible en métal d'un faisceau focalisé d'électrons de haute énergie (MeV) et de haute intensité (kA). Ce procédé lie très fortement les propriétés du faisceau d'électrons à ceux du faisceau X et donc à la qualité de la radiographie. Dans ce contexte, la thèse porte sur la compréhension de la dynamique du faisceau dans la diode à l'électron (c'est-à-dire juste avant son entrée dans la ligne accélératrice) ainsi que sur la caractérisation du plasma de velours dont sont issus les électrons qui composent le faisceau. Dans un premier temps, la dynamique du faisceau intense d'électrons a été étudiée à l'aide du code LSP reposant sur la méthode " Particle-In-Cell ". Les simulations réalisées ont été comparées avec des mesures effectuées sur l'injecteur d'un accélérateur linéaire à induction, implanté au CEA Valduc sur l'installation Epure. Grâce au modèle de simulation développé, une nouvelle diode à électrons mono-impulsion a été conçue, dimensionnée et réalisée pendant ce travail de thèse afin d'augmenter l'intensité du faisceau d'électrons de 2,0 kA à 2,6 kA permettant ainsi d'améliorer les performances radiographiques de l'installation. Dans un second temps, un modèle permettant d'étudier les mécanismes mis en jeu dans la production du faisceau d'électrons au niveau de plasma de cathode a été développé. Ce dernier est un modèle collisionnel-radiatif (MCR) 0D qui permet de décrire l'évolution de la densité des espèces d'un plasma dont la composition est directement liée aux molécules et atomes désorbés par la cathode de velours. Trois différents mélanges ont été étudiés impliquant de l'hydrogène, de l'oxygène et du carbone dont les proportions ont été estimées par des mesures LIBS (spectroscopie de plasma induit par laser).[...] / Intense X-ray flash radiography is used to take a stop-action picture of a material under extreme conditions like high densification, high temperature and high movement speed. The success of this kind of radiography is based on the quality of the X-ray source which must necessarily be penetrating (some MeV), intense (several rads), short (a few tens of ns) and small (a few mm). The X-ray pulse is generated from the bremsstrahlung radiation emitted during the interaction with a metal target of a focused electron beam of high energy (MeV) and high intensity (kA). This process strongly links the properties of the electron beam to those of the X-ray beam and thus to the quality of the radiography picture. In this context, the thesis is about the electron beam dynamics in the electron diode (i.e. just before electrons move towards the accelerator) as well as about the characterization of the velvet plasma from which electrons are extracted to form the beam. Firstly, the dynamics of the intense electron beam was studied using the LSP code based on the "Particle-In-Cell" method. The simulations were compared to measurements made on the injector of a linear induction accelerator, at the CEA Valduc center on the Epure facility. Based on the developed simulation model, a new single-pulse electron diode was designed, sized and realized during this thesis to increase the intensity of the electron beam from 2.0 kA to 2.6 kA, thus improving the radiographic performances of the facility. In a second step, a model allowing to study the mechanisms involved in the production of the electron beam from the cathode plasma was developed. This latter is a collisional-radiative model (CRM) 0D describing the evolution of the plasma species density of a plasma whose composition is directly related to the molecules and atoms desorbed by the velvet cathode. [...]

Plasma hors équilibre

Faisceau d'électrons

Accélérateur linéaire à induction

Cathode de velours

Radiographie éclair

Spectroscopie d'émission

Simulations électromagnétiques

Particle-in-cell

Non-equilibrium plasma

Electron beam

Linear induction accelerator

Velvet cathode

Flash radiography

Collisionnal-radiative model

Emission spectroscopy

Electromagnetic simulation

Particle-in-cell

Studies of Accelerator-Driven Systems for Transmutation of Nuclear Waste / Studier av acceleratordrivna system för transmutation av kärnavfall

Dahlfors, Marcus

January 2006

<p>Accelerator-driven systems for transmutation of nuclear waste have been suggested as a means for dealing with spent fuel components that pose potential radiological hazard for long periods of time. While not entirely removing the need for underground waste repositories, this nuclear waste incineration technology provides a viable method for reducing both waste volumes and storage times. Potentially, the time spans could be diminished from hundreds of thousand years to merely 1.000 years or even less. A central aspect for accelerator-driven systems design is the prediction of safety parameters and fuel economy. The simulations performed rely heavily on nuclear data and especially on the precision of the neutron cross section representations of essential nuclides over a wide energy range, from the thermal to the fast energy regime. In combination with a more demanding neutron flux distribution as compared with ordinary light-water reactors, the expanded nuclear data energy regime makes exploration of the cross section sensitivity for simulations of accelerator-driven systems a necessity. This fact was observed throughout the work and a significant portion of the study is devoted to investigations of nuclear data related effects. The computer code package EA-MC, based on 3-D Monte Carlo techniques, is the main computational tool employed for the analyses presented. Directly related to the development of the code is the extensive IAEA ADS Benchmark 3.2, and an account of the results of the benchmark exercises as implemented with EA-MC is given. CERN's Energy Amplifier prototype is studied from the perspectives of neutron source types, nuclear data sensitivity and transmutation. The commissioning of the n_TOF experiment, which is a neutron cross section measurement project at CERN, is also described.</p>

Nuclear physics

transmutation

accelerator-driven systems

Energy Amplifier

subcritical reactors

nuclear waste

Monte Carlo simulation

burnup

actinides

fission products

benchmark

nuclear data

neutron cross sections

sensitivity analysis

neutron source

spallation target

n_TOF experiment

neutron time-of-flight

cross section measurement

FLUKA

EA-MC

MCNP

MCNP-X

EADF

TRADE

Kärnfysik

Nuclear physics

Kärnfysik

Studies of Accelerator-Driven Systems for Transmutation of Nuclear Waste / Studier av acceleratordrivna system för transmutation av kärnavfall

Dahlfors, Marcus

January 2006

Accelerator-driven systems for transmutation of nuclear waste have been suggested as a means for dealing with spent fuel components that pose potential radiological hazard for long periods of time. While not entirely removing the need for underground waste repositories, this nuclear waste incineration technology provides a viable method for reducing both waste volumes and storage times. Potentially, the time spans could be diminished from hundreds of thousand years to merely 1.000 years or even less. A central aspect for accelerator-driven systems design is the prediction of safety parameters and fuel economy. The simulations performed rely heavily on nuclear data and especially on the precision of the neutron cross section representations of essential nuclides over a wide energy range, from the thermal to the fast energy regime. In combination with a more demanding neutron flux distribution as compared with ordinary light-water reactors, the expanded nuclear data energy regime makes exploration of the cross section sensitivity for simulations of accelerator-driven systems a necessity. This fact was observed throughout the work and a significant portion of the study is devoted to investigations of nuclear data related effects. The computer code package EA-MC, based on 3-D Monte Carlo techniques, is the main computational tool employed for the analyses presented. Directly related to the development of the code is the extensive IAEA ADS Benchmark 3.2, and an account of the results of the benchmark exercises as implemented with EA-MC is given. CERN's Energy Amplifier prototype is studied from the perspectives of neutron source types, nuclear data sensitivity and transmutation. The commissioning of the n_TOF experiment, which is a neutron cross section measurement project at CERN, is also described.

Nuclear physics

transmutation

accelerator-driven systems

Energy Amplifier

subcritical reactors

nuclear waste

Monte Carlo simulation

burnup

actinides

fission products

benchmark

nuclear data

neutron cross sections

sensitivity analysis

neutron source

spallation target

n_TOF experiment

neutron time-of-flight

cross section measurement

FLUKA

EA-MC

MCNP

MCNP-X

EADF

TRADE

Kärnfysik

Nuclear physics

Kärnfysik

Aufbau und Inbetriebnahme einer Photoneutronenquelle

Greschner, Martin

18 July 2013

Das Institut für Kern- und Teilchenphysik (IKTP) der Technischen Universität Dresden (TUD) hat im Forschungszentrum Dresden-Rossendorf (FZD) ein Labor zur Untersuchung von neutroneninduzierten kernphysikalischen Prozessen in Materialien, die für die Fusionsforschung relevant sind, aufgebaut. Das Labor ist ausgestattet mit drei intensiven Neutronenquellen: einer 14 MeV-Neutronenquelle, einer weißen kontinuierlichen Photoneutronen-Quelle, die näher in dieser Arbeit beschrieben wird, und einer gepulsten Photoneutronen-Quelle, die vom FZD inKooperation mit der TUD aufgebaut wurde. Die kontinuierliche Photoneutronen-Quelle basiert auf einem Radiator aus Wolfram (engl. Tungsten Photoneutron Source (TPNS)). TPNS nutzt die im ELBE-Beschleuniger (Elektronen Linearbeschleuniger für Strahlen hoher Brillianz und niedriger Emittanz (ELBE)) beschleunigten Elektronen zur Neutronenerzeugung. Der Prozess läuft über Zwischenschritte ab, indem bei der Abbremsung der Elektronen im Radiator Bremsstrahlungsphotonen entstehen, die anschließend Neutronen durch (γ,xn)-Reaktionen erzeugen. Das Neutronenspektrum der TPNS kann mittels Moderatoren so modifiziert werden, dass es dem in der ersten Wand im Fusionsreaktor entspricht. Dies ermöglicht Untersuchungen mit einem für einen Fusionsreaktor typischen Neutronenspektrum. Die technische Verwirklichung des Projektes, die Inbetriebnahme der Anlage sowie die Durchführung der ersten Experimente zur Neutronenerzeugung ist Inhalt dieser Arbeit. Die Neutronenquelle ist insbesondere für qualitative Untersuchungen in der Fusionsneutronik bestimmt. Der Fusionsreaktor produziert, im Vergleich zu einem Spaltungsreaktor, keine langlebigen Isotope als Abfall. Die wesentliche Aktivität des Reaktors ist in Konstruktionsmaterialien akkumuliert. Durch sorgfältige Auswahl der Materialien kann man die Aktivierung minimieren und damit künftig wesentlich weniger radioaktives Inventar produzieren als in Spaltreaktoren. Ziel der kernphysikalischen Untersuchungen ist, solche Materialien für den Aufbau eines Fusionsreaktors zu erforschen, die niedrigaktivierbar sind, das heißt wenig Aktivität akkumulieren können, und eine Halbwertzeit von einigen Jahren haben. Es ist das Ziel, alle Konstruktionsmaterialien nach 100 Jahren wiederverwenden zu können. Die Neutronenflussdichte einer Photoneutronenquelle ist einige Größenordnungen höher als die, die mittels eines DT-Neutronengenerators mit anschließender Moderation erreicht werden kann. Die gesamte Arbeit ist in drei Teile geteilt. Der erste Teil leitet in die Problematik der Energieversorgung ein und zeigt die Kernfusion als eine vielversprechende Energiequelle der naher Zukunft auf. Das Neutronenlabor der TUD, in dem die TPNS aufgebaut ist, wird ebenfalls kurz vorgestellt. Der zweite Teil befasst sich mit der TPNS selbst, mit ihrem physikalischen Entwurf, der Konstruktion und dem Aufbau bis zu der Inbetriebnahme sowie dem ersten Experiment an der TPNS. Der letzte, dritte Teil ist die Zusammenfassung der vorhandenen Ergebnisse und gibt einen Ausblick auf die zukünftige Vorhaben. / The Institute for Nuclear and Particle Physics at the Technische Universität Dresden (TUD) has build a neutron physics laboratory at Forschungszentrum Dresden-Rossendorf (FZD) to investigate nuclear processes in materials. The experiments are focused on materials relevant to nuclear fusion. The laboratory is equipped with three intensive neutron sources. The first is a 14 MeV monochromatic neutron source based on the DT reaction (owned by TUD); the other two are continuous and pulsed white photoneutron sources based on (γ,xn) reactions. One pulsed photoneutron source is realized by FZD in cooperation with the TUD. The continuous photoneutron source utilises a tungsten radiator (Tungsten Photoneutron Source) to produce neutrons with a wide energy spectra. The TPNS uses the ELBE-accelerator as a source of electrons for neutron production. This process involves an intermediate step, where slowed down electrons produce bremsstrahlung (γ -rays) absorbed by tungsten nuclei. Consecutively, the excited nuclei emit neutrons. The neutron flux of the photoneutron source is five orders of magnitude higher than the flux of the DT neutron sources with appropriate moderation. The neutron spectrum of TPNS can be modified by moderators, in such a way that the spectrum is comparable to that in the first wall of a Tokamak-Reactor. That allows investigations with the typical neutron spectrum of the fusion reactor. The technical solution, initial operation and the first experiment are described in this work. The neutron source is, in particular, dedicated to quantitative investigations in fusion neutronics. A fusion reactor produces radioactive isotopes as a nuclear waste. The main activity is accumulated in the structural materials. Carefully selected structural materials can significantly minimize the activity and thereby the amount of nuclear waste. The purpose of this project is to find constructional materials with half-lives shorter than several years, which can be recycled after about 100 years. The work is divided into three parts. The first part is dedicated to the energy supply problem and nuclear fusion is addressed as a promising solution of the near future. The neutron laboratory housing the TPNS is also briefly described. The second part deals with the tungsten photoneutron source, the design, construction, operation and the first experiments for neutron production. The third part summarises results and presents an outlook for future experiments with the TPNS.

ITER

Kernfusion

Wolfram

DENSIMET

Weiße Photoneutronenquelle

schnelle Neutronen

Blanket

kontinuierliches Neutronenspektrum

FEM

Helium

Heliumkuhlung

ELBE-Beschleuniger

Bremsstrahlung

Aktivierung

Speicherprogrammierbare Steuerung

SPS

niedrigaktvierbare Materialien

Transmutation

IFMIF

Konstruktion

CAD

ITER

Nuclear fusion

Tungsten

DENSIMET

White neutron source

Fast neutrons

Blanket

Continuous neutron spectrum

FEM

Helium cooling

ELBE Accelerator

Bremsstrahlung

PLC

Low-activation materials

Transmutation

IFMIF

design

CAD

ddc:530

rvk:UR 9000

rvk:UN 6130

治療溶電子線のエネルギ-および生体等価物質中吸収線量分布直読装置の研究開発

青山, 隆彦, 前越, 久, 津坂, 昌利, 小山, 修司

03 1900

科学研究費補助金 研究種目:基盤研究(C)(2) 課題番号:07680528 研究代表者:青山 隆彦 研究期間:1995-1996年度

医用加速器

シンチレ-ションファイバ-

電子線計測

吸収線量

放射線治療

電子線エネルギ-

ビ-ムモニタ-

深部吸収線量分布

生体等価物質

Radiation therapy

Electron beam measurement

Medical accelerator

Scintillating fiber

Beam monitor

Absorbed dose

Dose distribution

Electron beam energy

An explorative study of the technology transfer coach as a preliminary for the design of a computer aid

Jönsson, Oscar

January 2014

The university technology transfer coach has an important role in supporting the commercialization of research results. This thesis has studied the technology transfer coach and their needs in the coaching process. The goal has been to investigate information needs of the technology transfer coach as a preliminary for the design of computer aids.Using a grounded theory approach, we interviewed 17 coaches working in the Swedish technology transfer environment. Extracted quotes from interviews were openly coded and categorized. The analysis show three main problem areas related to the information needs of the technology transfer coach; awareness, communication, and resources. Moreover, 20 features for future computer aids were extracted from the interview data and scenarios and personas where developed to exemplify the future use of computer aids.We conclude that there is a need for computer support in the coaching process. Such systems should aid the coach in; awareness, aiding the coach to focus on meetings; communication, aid the coach to transfer commercialisation knowledge; and resources, aid the coach in accessing and delivering of resources to the coachee. However, it is imperative that the computer aids do not interfere with the coach current process; and that the computer aid is not seen as the sole solution.

technology transfer

coaching

innovationskontorett

linköpings universitet holding ab

oscar jönsson

oskar jönsson

grow

business model canvas

open innovation accelerator

coach

coachee

persona

g.r.o.w

NABC

need aproach benefit cost

TTO

TTOS

TT

computer

aid

software

support

linköping university

computer science

coachning

coach

innovationskontorett

linköpings universitet

coacha

kunskapsöverföring

oscar jönsson

oskar jönsson

GROW

G.R.O.W

NABC

N.A.B.C

OIA

innovationskontor

Vida-média do estado isomérico 7(-) do núcleo ímpar-ímpar 68Ga / Lifetime of the 7(-) isomeric state of the odd-odd nucleus 68Ga

Rafael Escudeiro

13 April 2018

Estados Nucleares isoméricos são estados que decaem com vidas-médias longas ( T1/2 > 10 ns) e revelam, em geral, uma grande mudança no momento angular no seu decaimento, um pequeno elemento de matriz ou uma baixa energia de transição. Através da medida da vida-média de estados nucleares é possível obter informações sobre a função de onda desse estado, representando um teste rigoroso para modelos nucleares. Neste trabalho foi utilizado um sistema desenvolvido no Laboratório Aberto de Física Nuclear (LAFN) da Universidade de São Paulo chamado SIStema para Medida de Estados Isoméricos (SISMEI), que utiliza coincidência atrasada entre partículas evaporadas numa reação nuclear e raios gama emitidos pelo estado isomérico. O SISMEI consiste de cintiladores plásticos para detecção das partículas, detectores de germânio hiperpuro (HPGe) e iodeto de sódio (NaI(Tl)) para raios gama, associados a uma eletrônica de coincidência, instalado no acelerador Pelletron (8UD) do LAFN. Neste trabalho, realizou-se um experimento para medir o estado isomérico 7(-) (E = 1229,87(4) keV) do 68Ga. A tomada de dados durou cerca de 80 horas com uma taxa de eventos de aproximadamente 80000 contagens por hora. O resultado obtido foi T 1/2 = 60, 8(11) ns, que é compatível com os resultados experimentais de outros trabalhos, porém, mais preciso. A estrutura desse núcleo foi calculada através do Modelo de Camadas em Larga Escala considerando-se duas interações residuais diferentes FPG e JUN45; os resultados foram comparados entre si, juntamente com os valores obtidos em outros trabalhos. Os cálculos realizados com o Modelo de Camadas reproduziram relativamente bem a energia e a ordem dos estados excitados do 68Ga, a interação FPG conseguiu descrever melhor a probabilidade de transição quadrupolar elétrica B(E2) diretamente ligada à vida-média do estado. / Isomeric nuclear states are nuclear states which decay with long lifetimes (T1/2 > 10 ns); their study generally reveals, a large change in angular momentum in its decay, a small matrix element or a small transition energy. By measuring lifetimes of isomeric states it is possible to obtain information about this states wave function, being a robust test for nuclear models. In this work, a system developed at the Laboratório Aberto de Fsica Nuclear (LAFN) of University of São Paulo called System for the Measurement of Isomeric States (SISMEI) was utilized. Delayed coincidence between evaporated particles in a nuclear reaction and the delayed gamma-rays emitted from the isomeric state was used to measure lifetimes. SISMEI is composed of plastic scintillators for particle detection, hiperpure germanium detectors (HPGe) and sodium iodide (NaI(Tl)) for gamma-ray detection, coupled to a coincidence system, located on 30A beam line of the Pelletron (8UD) accelerator - LAFN. In the present work, an experiment to measure the 7 (-) (E = 1229.87(4) keV) isomeric state of 68Ga was performed. The experiment took about 80 hours with an event rate of about 80000 counts per second. The measured value was T 1/2 = 60.8(11) ns, which is compatible, but more accurate, with experimental results of other authors. The nuclear structure of this nucleus was calculated with the Large Scale Shell Model by using two different residual interactions FPG and JUN45; the results were compared with the known values. The structure calculated with LSSM described the energy states and the order of excited states relatively well; the FPG interaction was capable to describe better the quadrupolar electrical transition probability B(E2), which is direct related to predicting the state lifetime.

acelerador Pelletron

coincidência gama-partícula atrasada

espectroscopia de raios gama

estados isoméricos

estrutura nuclear

física nuclear

Modelo de Camadas em Larga Escala

reações de fusão-evaporação

SISMEI

vida-média

delayed coincidence

fusion-evaporation reactions

gamma-particle coincidence

gamma-ray spectroscopy

isomeric states

Large Scale Shell Model

lifetimes

nuclear physics

nuclear structure

Pelletron accelerator

SISMEI

Space Charge Modeling at the Integer Resonance for the CERN PS and SPS

Titze, Malte

11 June 2020

Die elektromagnetische Wechselwirkung der Teilchen untereinander, wie sie typischerweise in einem Strahl hoher Intensität in den CERN Beschleunigern auftritt, kann in Langzeitsimulationen nicht vernachlässigt werden. Simulationen sind insbesondere notwendig, um diese Beschleuniger zu optimieren und die zugrundeliegende kohärente und inkohärente Dynamik besser zu verstehen. Die Auswirkungen der unumgänglichen Vereinfachungen in der Modellierung der komplizierten Dynamik müssen deshalb untersucht werden. Wir gehen diese Aufgabe an, indem wir sechs verschiedene Strahlführungsmodelle am CERN Proton Synchrotron (PS) und am Super Proton Synchrotron (SPS) untersuchen, die wir dynamisch in der Nähe von horizontalen Integer-Resonanzen operieren. Die sechs Modelle, welche insgesamt in den beiden bewährten Programmpaketen MAD-X und PyOrbit implementiert sind, werden mit den jeweiligen Messungen an beiden Maschinen verglichen, wobei der Schwerpunkt hier auf dem PS liegt. / In long-term tracking simulations of high-intensity beams which are typical in the CERN accelerators, the electromagnetic interaction between the individual particles can not be neglected. Simulations are required to optimize the performance of the accelerators, and to better understand the involved coherent and incoherent dynamics. The impact due to the unavoidable simplifications when modeling the complex dynamics must therefore be studied. We approach this task by examining six different tracking models, applied to the CERN Proton Synchrotron (PS) and the Super Proton Synchrotron (SPS), both of which were dynamically operated near horizontal integer resonances. The six models, which are overall implemented in the well-known program packages MAD-X and PyOrbit, are compared to beam-based measurements on both machines, with the PS as the main emphasis.

Teilchenbeschleuniger

Raumladung

Resonanz

PyOrbit

MAD-X

Symplektische Abbildung

Proton Synchrotron

Super Proton Synchrotron

CERN

Speicherring

Kombinierte-Funktionen Magnet

Teilchendynamik

particle accelerator

space charge

resonance

PyOrbit

MAD-X

symplectic map

Proton Synchrotron

CERN

storage ring

Super Proton Synchrotron

Combined function magnet

particle dynamics

530 Physik

UN 6100

ddc:530

Aufbau und Inbetriebnahme einer Photoneutronenquelle

Greschner, Martin

01 July 2013

Das Institut für Kern- und Teilchenphysik (IKTP) der Technischen Universität Dresden (TUD) hat im Forschungszentrum Dresden-Rossendorf (FZD) ein Labor zur Untersuchung von neutroneninduzierten kernphysikalischen Prozessen in Materialien, die für die Fusionsforschung relevant sind, aufgebaut. Das Labor ist ausgestattet mit drei intensiven Neutronenquellen: einer 14 MeV-Neutronenquelle, einer weißen kontinuierlichen Photoneutronen-Quelle, die näher in dieser Arbeit beschrieben wird, und einer gepulsten Photoneutronen-Quelle, die vom FZD inKooperation mit der TUD aufgebaut wurde. Die kontinuierliche Photoneutronen-Quelle basiert auf einem Radiator aus Wolfram (engl. Tungsten Photoneutron Source (TPNS)). TPNS nutzt die im ELBE-Beschleuniger (Elektronen Linearbeschleuniger für Strahlen hoher Brillianz und niedriger Emittanz (ELBE)) beschleunigten Elektronen zur Neutronenerzeugung. Der Prozess läuft über Zwischenschritte ab, indem bei der Abbremsung der Elektronen im Radiator Bremsstrahlungsphotonen entstehen, die anschließend Neutronen durch (γ,xn)-Reaktionen erzeugen. Das Neutronenspektrum der TPNS kann mittels Moderatoren so modifiziert werden, dass es dem in der ersten Wand im Fusionsreaktor entspricht. Dies ermöglicht Untersuchungen mit einem für einen Fusionsreaktor typischen Neutronenspektrum. Die technische Verwirklichung des Projektes, die Inbetriebnahme der Anlage sowie die Durchführung der ersten Experimente zur Neutronenerzeugung ist Inhalt dieser Arbeit. Die Neutronenquelle ist insbesondere für qualitative Untersuchungen in der Fusionsneutronik bestimmt. Der Fusionsreaktor produziert, im Vergleich zu einem Spaltungsreaktor, keine langlebigen Isotope als Abfall. Die wesentliche Aktivität des Reaktors ist in Konstruktionsmaterialien akkumuliert. Durch sorgfältige Auswahl der Materialien kann man die Aktivierung minimieren und damit künftig wesentlich weniger radioaktives Inventar produzieren als in Spaltreaktoren. Ziel der kernphysikalischen Untersuchungen ist, solche Materialien für den Aufbau eines Fusionsreaktors zu erforschen, die niedrigaktivierbar sind, das heißt wenig Aktivität akkumulieren können, und eine Halbwertzeit von einigen Jahren haben. Es ist das Ziel, alle Konstruktionsmaterialien nach 100 Jahren wiederverwenden zu können. Die Neutronenflussdichte einer Photoneutronenquelle ist einige Größenordnungen höher als die, die mittels eines DT-Neutronengenerators mit anschließender Moderation erreicht werden kann. Die gesamte Arbeit ist in drei Teile geteilt. Der erste Teil leitet in die Problematik der Energieversorgung ein und zeigt die Kernfusion als eine vielversprechende Energiequelle der naher Zukunft auf. Das Neutronenlabor der TUD, in dem die TPNS aufgebaut ist, wird ebenfalls kurz vorgestellt. Der zweite Teil befasst sich mit der TPNS selbst, mit ihrem physikalischen Entwurf, der Konstruktion und dem Aufbau bis zu der Inbetriebnahme sowie dem ersten Experiment an der TPNS. Der letzte, dritte Teil ist die Zusammenfassung der vorhandenen Ergebnisse und gibt einen Ausblick auf die zukünftige Vorhaben. / The Institute for Nuclear and Particle Physics at the Technische Universität Dresden (TUD) has build a neutron physics laboratory at Forschungszentrum Dresden-Rossendorf (FZD) to investigate nuclear processes in materials. The experiments are focused on materials relevant to nuclear fusion. The laboratory is equipped with three intensive neutron sources. The first is a 14 MeV monochromatic neutron source based on the DT reaction (owned by TUD); the other two are continuous and pulsed white photoneutron sources based on (γ,xn) reactions. One pulsed photoneutron source is realized by FZD in cooperation with the TUD. The continuous photoneutron source utilises a tungsten radiator (Tungsten Photoneutron Source) to produce neutrons with a wide energy spectra. The TPNS uses the ELBE-accelerator as a source of electrons for neutron production. This process involves an intermediate step, where slowed down electrons produce bremsstrahlung (γ -rays) absorbed by tungsten nuclei. Consecutively, the excited nuclei emit neutrons. The neutron flux of the photoneutron source is five orders of magnitude higher than the flux of the DT neutron sources with appropriate moderation. The neutron spectrum of TPNS can be modified by moderators, in such a way that the spectrum is comparable to that in the first wall of a Tokamak-Reactor. That allows investigations with the typical neutron spectrum of the fusion reactor. The technical solution, initial operation and the first experiment are described in this work. The neutron source is, in particular, dedicated to quantitative investigations in fusion neutronics. A fusion reactor produces radioactive isotopes as a nuclear waste. The main activity is accumulated in the structural materials. Carefully selected structural materials can significantly minimize the activity and thereby the amount of nuclear waste. The purpose of this project is to find constructional materials with half-lives shorter than several years, which can be recycled after about 100 years. The work is divided into three parts. The first part is dedicated to the energy supply problem and nuclear fusion is addressed as a promising solution of the near future. The neutron laboratory housing the TPNS is also briefly described. The second part deals with the tungsten photoneutron source, the design, construction, operation and the first experiments for neutron production. The third part summarises results and presents an outlook for future experiments with the TPNS.

info:eu-repo/classification/ddc/530

ddc:530

Exotic Decays of a Vector-liketop Partner at the LHC

Skwarcan-Bidakowski, Alexander

January 2019

An evaluation of how sensitive some ATLAS searches for new physics are to a new beyond standard model (BSM) vector-like quark (VLQ) and a pseudo Nambu-Goldstone boson (pNGB) scalar. This was done by simulating a signal containing these new particles and making a recast of it onto existing verified ATLAS searches for new physics at center-of-mass (CM) energy of 13 TeV (Run 2) at the Large Hadron Collider (LHC). Signals for recasting were tailored such that their final states would be appropriate in relation to each respective ATLAS search in order to use the same selection criteria as applied in the existing searches. The results are summarized in the form of significances (Z) for each masspoint of the new top-partner and S particle. Significances did not show any expectiation of excluding any masspoint in the examined mass range for the recasts at 95% CL. This suggests that a dedicated search for these particles in the considered masspoints would be required.

Particle physics

Vector-like quarks

VLQ

Composite Higgs model

CHM

Top-partner

pseudo

Nambu-Goldstone boson

pNGB

NGB

ATLAS

LHC

CMS

Significance

Recast

CheckMate

CM

MadGraph

Pythia

Delphes

Detector

Analysis

Hierarchy Problem

Exotic

Decay

QFT

Quantum Field Theory

fermions

bosons

Jets

photons

leptons

13 TeV

Missing Transverse Energy

momentum

hypothetical

selection criteria

Standard model

Signal

background

event

Higgs

Mechanism

Simulation

Confidence limit

Other Physics Topics

Annan fysik

Accelerator Physics and Instrumentation

Acceleratorfysik och instrumentering

Subatomic Physics

Subatomär fysik