Entropy-based diagnostics of criticality Monte Carlo simulation and higher eigenmode acceleration methodology

Shi, Bo

10 June 2010

Because of the accuracy and ease of implementation, Monte Carlo methodology is widely used in analysis of nuclear systems. The obtained estimate of the multiplication factor (keff) or flux distribution is statistical by its nature. In criticality simulation of a nuclear critical system, whose basis is the power iteration method, the guessed source distribution initially is generally away from the converged fundamental one. Therefore, it is necessary to ensure that the convergence is achieved before data are accumulated. Discarding a larger amount of initial histories could reduce the risk of contaminating the results by non-converged data but increases the computational expense. This issue is amplified for large loosely coupled nuclear systems with low convergence rate. Since keff is a generation-based global value, frequently no explicit criterion is applied to the diagnostic of keff directly. As an alternative, a flux-based entropy check available in MCNP5 works well in many cases. However, when applied to a difficult storage fuel pool benchmark problem, it could not always detect the non-convergence of flux distribution. Preliminary evaluation indicates that it is due to collapsing local information into a single number. This thesis addresses this problem by two new developments. First, it aims to find a more reliable way to assess convergence by analyzing the local flux change. Second, it introduces an approach to simultaneously compute both the first and second eigenmodes. At the same time, by computing these eigenmodes, this approach could increase the convergence rate. Improvement in these two areas could have a significant impact on practicality of Monte Carlo criticality simulations.

Monte Carlo

Convergence diagnositics

Eigenmode acceleration

Criticality (Nuclear engineering)

Monte Carlo method

Convergence

Eigenfunctions

Rapid frequency chirps of an Alfvén wave in a toroidal plasma

Wang, Ge, active 2013

30 September 2013

Results from models that describe frequency chirps of toroidal Alfvén eigenmode excited by energetic particles are presented here. This structure forms in TAE gap and may or may not chirp into the continuum. Initial work described the particle wave interaction in terms of a generic Hamiltonian for the particle wave interaction, whose spatial dependence was xed in time. In addition, we have developed an improved adiabatic TAE model that takes into account the spatial prole variation of the mode and the nite orbit excursion from the resonant ux surfaces, for a wide range of toroidal mode numbers. We have shown for the generic xed prole model that the results from the adiabatic model agree very well with simulation result except when the adiabatic condition breaks down due to the rapid variations of the wave amplitude and chirping frequency. We have been able to solve the adiabatic problem in the case when the spatial prole is allowed to vary in time, in accord with the structure of the response functions, as a function of frequency. All the models predict that up-chirping holes do not penetrate into the continuum. On the other hand clump structures, which down chirp in frequency may, depending on detailed parameters, penetrate the continuum. The systematic theory is more restrictive than the generic theory, for the conditions that enable clump to penetrate into the continuum. In addition, the systematic theory predicts an important nite drift orbit width eect, which eventually limits and suppresses a down-chirping response in the lower continuum. This interruption of the chirping occurs when the trapped particles make a transition from intersecting both resonant points of the continuum to just one resonant point. / text

Frequency chirps

Toroidal Alfvén eigenmode

Energetic particle

Adiabatic theory

Variational principle

Eigenmode multiplexing with SLM for volume holographic data storage

Takashima, Yuzuru, Chen, Guanghao, Miller, Bo E.

23 August 2017

The cavity supports the orthogonal reference beam families as its eigenmodes while enhancing the reference beam power. Such orthogonal eigenmodes are used as additional degree of freedom to multiplex data pages, consequently increase storage densities for volume Holographic Data Storage Systems (HDSS) when the maximum number of multiplexed data page is limited by geometrical factor. Image bearing holograms are multiplexed by orthogonal phase code multiplexing via Hermite- Gaussian eigenmodes in a Fe: LiNbO3 medium with a 532 nm laser at multiple Bragg angles by using Liquid Crystal on Silicon (LCOS) spatial light modulators (SLMs) in reference arms. Total of nine holograms are recorded with three angular and three eigenmode.

Holography

Data Storage

Spatial Light Modulator

Phase-code Multiplexing

Eigenmode Multiplexing

Lattice QCD study for the relation between confinement and chiral symmetry breaking / 格子QCDを用いた閉じ込めとカイラル対称性の自発的破れの関係性の研究

Doi, Takahiro

23 March 2017

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20174号 / 理博第4259号 / 新制||理||1612(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)准教授 菅沼 秀夫, 教授 國廣 悌二, 教授 川合 光 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

Lattice QCD

confinement

chiral symmetry breaking

Polyakov loop

Dirac eigenmode

400

Kinetic-magnetohydrodynamic Hybrid Simulation Study of Energetic-particle Driven Instabilities in Heliotron J / ヘリオトロンJにおける高エネルギー粒子駆動不安定性の運動論的磁気流体力学ハイブリッドシミュレーション研究

PANITH, ADULSIRISWAD

24 September 2021

京都大学 / 新制・課程博士 / 博士(エネルギー科学) / 甲第23538号 / エネ博第429号 / 新制||エネ||81(附属図書館) / 京都大学大学院エネルギー科学研究科エネルギー基礎科学専攻 / (主査)准教授 門 信一郎, 教授 中村 祐司, 教授 長﨑 百伸 / 学位規則第4条第1項該当 / Doctor of Energy Science / Kyoto University / DFAM

nuclear fusion

Alfvén eigenmode

energetic particle

stellarator

heliotron

simulation

MHD instability

501

Comparison of RF Heating in ASDEX Upgrade and ITER

Blennå, Axel, Kalldas, Mark

January 2022

The increased effects of global warming have been a driving force to further research and develop sustainable energy sources, such as fusion. In this study, two different fusion devices are compared in terms of ion cyclotron resonance heating (ICRH)of plasma. The two devices are the tokamaks ASDEX Upgrade and not yet built ITER. To make the comparison, ICRH was simulated in the two tokamaks using the FEMIC code. ASDEXUpgrade was simulated with a deuterium plasma and ITER was simulated both with a deuterium and a deuterium-tritium plasma. In all scenarios a 3% minority species concentration,consisting of helium-3, was introduced. The obtained results showa higher and more centered wave absorption in ITER, compared to ASDEX Upgrade. This is mainly due to the size difference of the tokamaks. The smaller plasma radius of ASDEX Upgrade allowed for more wave reflection in the plasma, resulting in standing waves that formed eigenmode patterns. For simulationsin ITER, the waves were absorbed before they could be reflected in the plasma. Instead of standing waves and eigenmode patterns,the waves behaved as beams, propagating in a narrow region of the plasma. This indicates that ITER is more effective in terms of ICRH, as the absorption is greater and more focused to the center, minimizing power losses to the surroundings. / De ökade konsekvenserna av den globala uppvärmningen har varit en drivkraft för fortsatt forskning och utveckling av hållbara energikällor, bland annat fusion. I den här studien jämförs två olika fusionsanläggningar med avseende på joncyklotronresonansuppvärmning (ICRH) av plasma. De två anläggningarna är tokamakerna ASDEX Upgrade och ännu inte byggda ITER. För att göra jämförelser simulerades ICRH i de två tokamakerna med hjälp av FEMIC-koden. ASDEX Upgrade simulerades med ett deuteriumplasma och ITER simulerades med både ett deuteriumoch ett deuterium-tritiumplasma. För alla scenarier introducerades en 3% minoritetskoncentration av helium-3. Resultaten visar en högre och mer centrerad vågabsorption i ITER jämfört med ASDEX Upgrade. Detta beror framför allt på storleksskillnaden mellan tokamakerna. Den kortare plasmaradien av ASDEX Upgrade tillät mer reflektion i plasmat, vilket resulterade i stående vågor som bildade egenmodsmönster. För simuleringar i ITER absorberades vågorna innan de kunde reflekteras i plasmat. I stället för stående vågor och egenmodsmönster uppförde vågorna sig som strålar som propagerade över en smal region i plasmat. Det här indikerar att ITER är mer effektiv med avseende på ICRH, då absorptionen re och mer centrerad, vilket minimerar effektförluster till omgivningen. / Kandidatexjobb i elektroteknik 2022, KTH, Stockholm

Fusion

ASDEX Upgrade

ITER

FEMIC

ICRH

eigenmode

beam

wave absorption

Elektroteknik och elektronik

Frequency Response Modeling of Additive Friction Stir Deposition Parts with Print Defects

Pennington, Brett Kenneth

03 June 2024

A change in a part's response to vibrations can be measured and utilized as a non-destructive testing method to detect deviations in the part's materials or geometry through processes such as laser acoustic resonance spectroscopy. This work focuses on leveraging vibration resonance to detect flaws in prints produced through additive friction stir deposition that arise through environmental contamination. More specifically, the use case considered is the printing of AA7075 in an iron oxide rich environment, where iron oxide dust or powder could accidentally be stirred into the printed material creating a print flaw. The modeling of printed parts contaminated with iron oxide to predict their natural frequencies is examined. Two different finite element models are discussed, which were created to represent contamination flaws with and without voids. The first model considers the case where a part is void-free. In this case, the model assumes a solid, homogeneous material condition in the stir region. The second model considers the case where voids are present in the part. This model leverages x-ray computed tomography data to build a representative mesh. These models show that with a well-understood part and corresponding flaw, it is possible to predict the natural frequencies of a flawed part. By leveraging the part vibration measurements and model predictions of known defects, it may be possible to gain insights into and characterize unknown print flaws. / Master of Science / An important aspect of product or part creation is checking consistency between parts. Methods that can verify a part is good without damaging the part are valuable, especially when only a few parts are being made, or there is a high chance of something going wrong. One way of checking a part is to shake it and watch how it reacts and bends. If there is a difference in how a part reacts to the shaking from a known good part, then there is a problem. This work examines creating computer simulations to predict how a part should react to shaking when it is good and how it should react when it has flaws. This work considers flaws caused by debris from the environment during part creation. This work also considers whether such debris causes holes or voids to form in the parts and conducts predictions with the holes included.

Additive friction stir deposition

finite element analysis

modeling

in-situ monitoring

non-destructive testing

natural frequency

frequency mode

eigenmode analysis

Experimental Investigations of Wave Motion and Electric Resistance in Collisionfree Plasmas

Wendt, Martin

January 2001

No description available.

Beam-plasma

Buneman Instability

Density gradient

Double layer

Electric field measurement

Electron beam

Electrostatic eigenmode

Finite element

HF probe

PIC simulation

van der Pol oscillator

Experimental Investigations of Wave Motion and Electric Resistance in Collisionfree Plasmas

Wendt, Martin

January 2001

No description available.

Beam-plasma

Buneman Instability

Density gradient

Double layer

Electric field measurement

Electron beam

Electrostatic eigenmode

Finite element

HF probe

PIC simulation

van der Pol oscillator

Etude de l'advection chaotique dans des mélangeurs à tiges, en écoulements ouverts et fermés

Gouillart, Emmanuelle

25 October 2007

Nous avons étudié le mélange de fluides visqueux dans des écoulements 2-D ouverts et fermés où des agitateurs créent de l'advection chaotique, i.e. des trajectoires lagrangiennes complexes. Notre étude, expérimentale, numérique et théorique, s'appuie sur deux types d'expériences de mélange chaotique, en domaine fermé et dans un canal ouvert. En système fermé, nous avons d'abord proposé une caractérisation topologique du mélange reposant sur l'enchevêtrement des trajectoires de points périodiques -- les "tiges fantômes". D'autre part, l'étude expérimentale du champ de concentration d'un colorant nous a permis de décrire le rôle des murs du domaine où se fait le mélange, pour les écoulements fermés comme ouverts. En fermé, la nature chaotique ou régulière des trajectoires initialisées près des bords détermine l'évolution du champ de concentration, même loin des bords. Nous avons ainsi observé une dynamique lente (algébrique) de l'homogénéisation quand la région chaotique s'étend jusqu'à des murs non-glissants. En ouvert, nous avons décrit l'évolution du champ de concentration dans, et en aval de la région de mélange, résultant de l'injection d'un blob de colorant. Nous avons décrit les éléments mal mélangés qui s'échappent aux temps courts, et l'apparition d'un motif permanent (auto-similaire) aux temps longs, déterminé par les orbites périodiques de la région de mélange. Des modifications de ce scénario apparaissent quand la région de mélange va jusqu'aux murs. Enfin, une modélisation à base de transformation du boulanger généralisée nous a permis de comprendre l'essentiel des mécanismes rencontrés.

mélange chaotique

mélangeur industriel

fluides visqueux

strange eigenmode

systèmes ouverts

selle chaotique

transformation du boulanger

mélange topologique

orbites périodiques