Study of zero-chromatic FFAG synchrotron for muon acceleration / ミューオン加速のための零色収差FFAGシンクロトロンの研究

PLANCHE, Thomas

24 November 2010

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第15726号 / 工博第3340号 / 新制||工||1505(附属図書館) / 28271 / 京都大学大学院工学研究科原子核工学専攻 / (主査)教授 森 義治, 教授 伊藤 秋男, 教授 中島 健 / 学位規則第4条第1項該当

加速器

FFAG

ミューオン

500

Study of zero-chromaticity in FFAG accelerators / FFAG加速器における零色収差に関する研究

LAGRANGE, Jean-Baptiste Henri Raymond

26 March 2012

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第16846号 / 工博第3567号 / 新制||工||1539(附属図書館) / 29521 / 京都大学大学院工学研究科原子核工学専攻 / (主査)教授 森 義治, 教授 伊藤 秋男, 教授 中島 健 / 学位規則第4条第1項該当

加速器

FFAG

ミューオン

500

Study of serpentine acceleration in zero-chromatic FFAG accelerators / 零色収差FFAG加速器における蛇行加速に関する研究

Yamakawa, Emi

25 March 2013

Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(工学) / 甲第17563号 / 工博第3722号 / 新制||工||1567(附属図書館) / 30329 / 京都大学大学院工学研究科原子核工学専攻 / (主査)教授 森 義治, 教授 伊藤 秋男, 教授 中島 健 / 学位規則第4条第1項該当

zero-chromatic FFAG

fixed rf frequency acceleration

high-intensity beam

500

Beam dynamics studies of the EMMA linear non-scaling FFAG

Garland, James Matthew

January 2014

The development of charged particle accelerators is today reaching far beyond the realm of fundamental particle physics research. Many non-trivial social and political problems may find part of their solution lies in accelerator physics. For example, with fossil fuels becoming ever more controversial and expensive to obtain, the use of Accelerator Driven Sub-critical Reactors (ADSR) powered by rapid cycling, high current proton accelerators and thorium fuel could become part of the energy solution. Through the simplicity of the Bragg peak, cancer therapy could be enhanced through the use of high repetition rate, variable energy proton accelerators small enough to use in treatment centres. The growing problem of long lived nuclear waste storage could become a moot point through the use of high current, high power proton accelerators coupled with neutron spallation. These rapidly growing areas of study are fuelled by the development of the Fixed-Field Alternating-Gradient (FFAG) accelerator, and more recently the non-scaling FFAG. The FFAG has the ability to accelerate high current, low quality bunches of particles in very short time scales due to the fixed-field nature of its magnets. This rapid acceleration can be of the order 500 nanoseconds to 1 microsecond meaning a fast cycling rate of the machine is possible. This allows the realistic development of the ADSR, proton therapy machine and even the muon accelerator. The Electron Model with Many Applications (EMMA) accelerator is the world's first linear non-scaling FFAG and is an electron proof-of-principle accelerator based at Daresbury Laboratory, UK. EMMA can accelerate over its energy range of 10 - 20 MeV in approximately 5 - 10 machine revolutions (~275 - 500 nanoseconds) using fixed-frequency novel acceleration techniques. The accelerator contains fixed-field, constant gradient quadrupole magnets which provide all the bending and focussing to the particles. Due to the linear non-scaling nature of EMMA, many transverse integer tune values are crossed which typically cause resonant effects resulting in bunch degradation and loss. It was proposed and demonstrated that rapid crossing (in 5 - 10 turns) of integer tune values in EMMA did not result in transverse amplitude growth and particle loss. If the wider societal goals of the non-scaling FFAG are to be realised, protons and other heavy ions must be accelerated. Current technological limitations dictate that longer acceleration times of the order 1000's of turns would be necessary in proton machines of similar design to EMMA. Hence slower integer tune crossing was studied using acceleration in a synchrotron bucket in EMMA. It was found experimentally that below the nominal EMMA operating acceleration rate of 2.0 MV per turn, instabilities begin to manifest. This was indicated in the growth of closed orbit distortion (COD) and through simulation it was found that betatron amplitude growth coupled with COD resulted in eventual loss of particles to the physical aperture when crossing integer tunes. Through simulation, the amplitude growth of particles crossing integer tunes in the EMMA non-scaling FFAG was found to agree with a theory of resonance crossing proposed by R. Baartman. This theory shows that amplitude growth is proportional to $1/\sqrt(Q')$ where $Q'$ is the tune crossing rate of the particles. This means that the slower the acceleration, the slower an integer tune is crossed and hence more amplitude is gained. It was also shown that strength of the magnetic errors driving the resonant conditions was proportional to the amplitude growth.

539.7

Les accélérateurs à champ fixe et gradient alterné FFAG et leur application médicale en protonthérapie.

Fourrier, Joris

17 October 2008

La radiothérapie utilise des faisceaux de particules dans le but d'irradier et d'éliminer les tumeurs cancéreuses tout en épargnant au maximum les tissus sains. La perte d'énergie en forme de pic de Bragg des protons dans la matière permet une amélioration balistique du dépôt de la dose par rapport aux rayons X. Le volume irradié peut ainsi être précisément ajusté au volume tumoral. Cette thèse, dans le cadre du projet RACCAM, vise à étudier et à mettre au point le design d'une installation de protonthérapie basée sur un accélérateur de particules à champ fixe et à gradient alterné FFAG dans le but de construire un aimant FFAG à secteur spiral pour validation. Nous présentons tout d'abord la protonthérapie pour définir un cahier des charges médicales définissant les critères techniques d'une installation de protonthérapie. Puis nous introduisons les accélérateurs FFAG par une présentation des projets passés et en cours dans le monde avant de développer la théorie de la dynamique faisceau dans le cas de l'optique à focalisation invariante. Nous décrivons ensuite les outils de modélisation et simulation mis au point pour étudier cette dynamique faisceau dans une optique FFAG à focalisation invariante et à secteur spiral. Nous expliquons par la suite la recherche des paramètres de l'optique ayant abouti à la construction d'un aimant prototype. Enfin, nous décrivons l'installation de protonthérapie du projet RACCAM depuis le cyclotron injecteur jusqu'au système d'extraction.

[PHYS] Physics

Radiothérapie

protonthérapie

pic de Bragg

dépôt de dose

cahier des charges

accélérateur FFAG

focalisation invariante

aimant à secteur spiral

dynamique faisceau

modélisation

simulation numérique

prototypage