Global ETD Search

1	Graphene on nanoscale gratings for THz electron-beam radiation and plasmonics Tantiwanichapan, Khwanchai 21 June 2016 (has links) Terahertz (THz) technologies have numerous applications such as biological and medical imaging, security screening, remote sensing, and industrial process control. However, the lack of practical THz sources and detectors is still a significant problem limiting the impact of these applications. In this Thesis work, three novel THz radiation mechanisms are proposed and investigated, based on the distinctive electronic properties of charge carriers in 2D single-layer graphene and related 1D conductors (i.e., graphene nanoribbons and carbon nanotubes), combined with the use of nanoscale dielectric gratings. Numerical simulations as well as fabrication and characterization activities are carried out. The first proposed radiation mechanism is based on the mechanical corrugation of a single-layer sheet of graphene or 1D carbon conductor, deposited on a lithographically-defined sinusoidal grating. In the presence of a dc voltage, carriers will therefore undergo periodic angular motion and correspondingly radiate (similar to cyclotron emission but without the need for any external magnetic field). My numerical simulations indicate that technologically significant output power levels can correspondingly be obtained at geometrically tunable THz frequencies. Initial graphene samples on sinusoidal gratings were fabricated and found to undergo significant strain redistribution, which affects their structural quality. Charge carriers moving in a flat sheet of graphene or linear 1D carbon conductor parallel to a nanoscale grating can also produce THz radiation based on the Smith-Purcell effect. The role of the grating in this case is to diffract the evanescent electromagnetic fields produced by the moving electrons and holes so that THz light can be radiated. Once again, numerical simulations indicate that this approach is promising for the realization of ultra-compact THz sources capable of room-temperature operation. Initial experimental results with ultra-high-mobility graphene samples embedded in boron nitride films show promising THz electroluminescence spectra. The last approach considered in this Thesis involves graphene plasmons at THz frequencies, which can be excited through the decay of hot electrons injected with an applied bias voltage. A nearby grating can then be used to outcouple the guided electromagnetic fields associated with these collective charge oscillations into radiation. The excitation of these THz plasmonic resonances at geometrically tunable frequencies has been demonstrated experimentally via transmission spectroscopy measurements. / 2017-06-21T00:00:00Z Electrical engineering Graphene Plasmonics THz electron-beam radiation
2	Development of a Low Energy Electron Accelerator System for Surface Treatments and Coatings Phantkankum, Nuttapong January 2015 (has links) No description available. Radiation Technology
3	A procedure to predict the energy harvest of photovoltaic arrays using only global horizontal radiation measurements Reddy, Niveditha Hanumantha 01 November 2010 (has links) This thesis uses the results of analysis of data recorded at a solar monitoring station in West Texas and the knowledge from an existing solar radiation estimation model to develop a methodology to predict the energy output from a panel at a site using only partial radiation data - global horizontal radiation measurements. The prediction using partial data is validated against estimates acquired using the complete radiation data and constraints are defined for accurate prediction. The methodology presented in this thesis can be used to accurately predict the solar power/energy incident on a collector at any location possessing global horizontal radiation measurements. / text Global horizontal Diffuse horizontal Beam radiation Zenith angle Incident solar power
4	Multiple-source models for the beams from an Elekta SL25 clinical accelerator / Sego, Zdenko, January 1900 (has links) Thesis (M.Sc.) - Carleton University, 2006. / Includes bibliographical references (p. 113-119). Also available in electronic format on the Internet.
5	System Solution for In-Beam Positron Emission Tomography Monitoring of Radiation Therapy Shakirin, Georgy 14 July 2009 (has links) In-beam Positron Emission Tomography (PET) is a system for monitoring high precision radiation therapy which is in the most cases applied to the tumors near organs at risk. High quality and fast availability of in-beam PET images are, therefore, extremely important for successful verification of the dose delivery. Two main problems make an in-beam PET monitoring a challenging task. Firstly, in-beam PET measurements result in a very low counting statistics. Secondly, an integration of the PET scanner into the treatment facility requires significant reduction of the sensitive surface of the scanner and leads to a dual-head form resulting in imaging artifacts. The aim of this work is to bring the imaging process by means of in-beam PET to optimum quality and time scale. The following topics are under consideration: - analysis of image quality for in-beam PET; - image reconstruction; - solutions for building, testing, and integration of a PET monitoring system into the dedicated treatment facility. info:eu-repo/classification/ddc/610 ddc:610 PET, Rekonstruktion, Strahlentherapie
6	Oxygen effect in medical ion beam radiation combined with nanoparticles / Effet de l’oxygène dans l'irradiation par des ions médicaux combinés avec des nanoparticules Bolsa Ferruz, Marta 18 December 2017 (has links) Environ 50% des patients recevant un traitement contre le cancer bénéficient de la radiothérapie. La radiothérapie conventionnelle consiste à utiliser des rayons X de haute énergie capables de traverser les tissus et de traiter des tumeurs situées en profondeur de façon non-invasive. Malheureusement, les rayons X ne font pas la distinction entre les tumeurs et les tissus sains, qui peuvent donc être endommagés. Cette non-sélectivité est à l’origine de graves effets secondaires, voire du développement de cancers secondaires. Par conséquent, l’amplification des effets radiatifs au sein de la tumeur par rapport aux tissus environnants représente un défi majeur.L’hadronthérapie (traitement par faisceaux de protons ou d’ions carbone) est considérée comme l’une des techniques les plus prometteuses car, contrairement aux rayons X, la quantité d’énergie déposée atteint son maximum en fin de trajectoire. Lorsque le faisceau est réglé de manière à ce que ce maximum atteigne la tumeur, aucun dommage n’est causé aux tissus situés au-delà. Un autre avantage majeur est que les ions lourds sont plus efficaces pour traiter les tumeurs radiorésistantes. L’utilisation de cette technique est cependant restreinte du fait des dommages – plus faibles mais néanmoins significatifs – causés aux tissus normaux situés sur la trajectoire du faisceau d’ions en amont de la tumeur. Afin d’améliorer les performances de l’hadronthérapie, l’équipe a développé à l’ISMO une nouvelle stratégie combinant l’utilisation de nanoparticules (NPs) métalliques avec l’irradiation par faisceaux d’ions. L’utilisation de NPs a pour but non seulement d’amplifier les effets des rayonnements dans la tumeur mais également d’améliorer l'imagerie médicale à l’aide des mêmes agents (théranostic). Les NPs possèdent une chimie de surface permettant leur fonctionnalisation avec des ligands capable d’améliorer la biocompatibilité, la stabilité ainsi que la circulation sanguine et l’accumulation dans la tumeur. L’équipe a déjà démontré que les petites NPs d’or et de platine (≈ 3 nm) avaient la capacité d’amplifier les effets causés par les faisceaux d’ions carbone médicaux en présence d’oxygène. Cependant, les tumeurs radiorésistantes sont susceptibles de contenir des régions hypoxiques. Il est donc urgent de quantifier et de caractériser l’influence de l’oxygène sur l’effet radio-amplificateur. Le but de ma thèse était d’étudier l’influence de l’oxygène lors d’irradiations par des faisceaux d’ions médicaux en présence de NPs d’or et de platine. Pour cela, deux lignes de cellules cancéreuses humaines radiorésistantes ont été testées: HeLa (col de l’utérus) et BxPC-3 (pancréas). Plusieurs techniques d’irradiation ont été utilisées : des faisceaux d’ions carbone et hélium générés par « passive scattering » et des faisceaux d’ions carbone générés par « pencil beam scanning ». Les principaux résultats de cette étude sont les suivants. En condition oxique (concentration d’O₂ = 20%), une amplification des effets radiatifs a été observée pour les deux types de NPs (à concentration de métal égale). Ce phénomène se réduit à mesure que la concentration d’oxygène diminue mais reste significatif jusqu’à 0.5%. Aucune différence significative n’a été observée entre les deux lignes cellulaires. Il est intéressant de noter que la dépendance à l’oxygène varie en fonction de la technique d’irradiation utilisée. Une tentative d’explication de l’influence de l’oxygène par des processus moléculaires est proposée. Des perspectives de développements ultérieurs sont suggérées. / About 50% of the cancer patients who are treated benefit from radiation therapy. Conventional radiotherapy consists of high energy X-rays traveling through the tissues, so that deeply sited tumors are treated in a non-invasive way. Unfortunately, X-rays are not tumor selective and healthy tissues may be damaged. This lack of selectivity is responsible for severe side effects and/or secondary cancers. Hence, improving the differential of radiation effects between the tumor and surrounding tissues remains a major challenge. Particle therapy (treatment by protons or carbon ion beams) is considered as one of the most promising technique because, by opposition to X-rays, the energy deposition of ions is maximum at the end of their tracks. When the beam is tuned so that the maximum reaches the tumor, there is no damage induced in tissues siting after the tumor. Another important added value is that heavy ions are more efficient to treat radioresistant tumors. The use of this modality is however restricted by the low but significant damage that is induced to normal tissues located at the entrance of the track prior to reaching the tumor. To improve the performance of particle therapy, a new strategy based on the combination of high-Z nanoparticles with ion beam radiation has been developed by the group at ISMO. This approach aims at using nano-agents not only to increase radiation effects in the tumor but also to improve medical imaging with the same agent (theranostic). Nanoparticles present a remarkable surface chemistry, which allows functionalization with ligands able to improve biocompatibility, stability as well as blood circulation and accumulation in tumors. The group already demonstrated the efficiency of small (≈ 3 nm) gold and platinum nanoparticles to amplify the effects of medical carbon ions in normoxic conditions (in the presence of oxygen). However, radioresistant tumors may host hypoxic regions. It is thus urgent to quantify and characterize the influence of oxygen on the radio-enhancement effect. The goal of my thesis was to study the influence of oxygen on medical ion radiation effects in the presence of gold and platinum nanoparticles. This was performed using two radioresistant human cancer cell lines: HeLa (uterine cervix) and BxPC-3 (pancreas). Different radiation modalities were used: carbon and helium ion beams delivered by a passive scattering delivery system and carbon ion beams delivered by a pencil beam scanning system. The major results of this work are the following. In oxic conditions (O₂ concentration = 20%), an enhancement of ion radiation effects was observed for the two nanoparticles (at the same concentration in metal). This effect decreased with the oxygen concentration but remained significant for a concentration of 0.5%. No significant difference was found between the cell lines. Interestingly, the oxygen-dependence varied with the type of radiation. An attempt to explain the effect of oxygen by molecular processes is proposed. Perspectives of further developments are suggested. Hadronthérapie Nanoparticules Faisceau d’ions Radio-sensibilisation Hadrontherapy Nanoparticles Ion beam radiation Radio-enhancement
7	Omfattning av rörelse och volymförändringar i tumörområdet under strålbehandling av cervikal cancer : En litteraturstudie / Extent of movements and volume changes in the tumor area during radiotherapy treatment of cervical cancer Fridlund, Olivia January 2017 (has links) Bakgrund Extern strålbehandling är en viktig del av processen för behandling av cervikal cancer. Målet med denna typ av behandling är att bestråla tumörområdet med så hög dos som möjligt och omkringliggande frisk vävnad med så lite dos som möjligt. Ett problem som upptäckts är att rörelser i tumörområdet under behandling kan påverka precisionen av strålfältet. Syfte Syftet med litteraturstudien var att beskriva omfattning av rörelse och volymförändring i tumörområdet under strålbehandling av cervikal cancer. Metod Nio artiklar med kvantitativ design kvalitetsgranskades och resultaten sammanställdes med inspiration av Fribergs modell. Resultat Omfattning av rörelser och volymförändringar upptäcktes variera och är något som skiljer sig mellan individer. Valet av bildtagnings- och mätmetod har stor betydelse gällande patientsäkerhet och stråldos. Slutsats Hur mycket tumörområdet rör sig/förändras i volym var något som varierade mellan patienterna i studierna och det är därför viktigt att anpassa behandlingen efter dessa variationer. Olika metoder för bildtagning och mätning kan användas både för att upptäcka rörelser och volymförändringar i tumörområdet under extern strålbehandling. De olika metodernas fördelar bör noggrant vägas mot nackdelar innan användning för att hitta en optimal metod som främjar patientsäkerhet. / Background External radiation therapy is an important part when treating cervical cancer. The goal of this type of therapy is to irradiate the tumor area with the highest possible dose and minimize the dose given to the surrounding healthy tissue. One problem showed is that movement in the tumor area during treatment can cause problems regarding keeping the precision as high as possible. Aim The aim of this literature study was to describe the extent of movement and volume change in the tumor area during external radiotherapy treatment of cervical cancer. Method Nine articles with quantitative design were quality-reviewed and the results were compiled with inspiration from Friberg's model. Results The extent of movements and volume changes was discovered varying and is something that differs between individuals. The choice of imaging and measurement method is of great importance in terms of patient safety and radiation dose. Conclusions The extent of movement and change in volume varied between patients in the studies and it is therefore important to adjust the treatment according to these variations. Different methods of imaging and measurement can be used both to detect movements and volume changes in the tumor area during external radiation therapy. The benefits of the different methods should be carefully weighed against disadvantages before use to find an optimal method that promotes patient safety. organ movement cervical cancer external beam radiation therapy methods organrörelse cervikal cancer extern strålbehandling metoder Nursing Omvårdnad
8	Machine learning and augmented data for automated treatment planning in complex external beam radiation therapy Lempart, Michael January 2019 (has links) External beam radiation therapy is currently one of the most commonly used modalities for treating cancer. With the rise of new technologies and increasing computational power, machine learning, deep learning and artificial intelligence applications used for classification and regression problems have begun to find their way into the field of radiation oncology. One such application is the automated generation of radiotherapy treatment plans, which must be optimized for every single patient. The department of radiation physics in Lund, Sweden, has developed an autoplanning software, which in combination with a commercially available treatment planning system (TPS), can be used for automatic creation of clinical treatment plans. The parameters of a multivariable cost function are changed iteratively, making it possible to generate a great amount of different treatment plans for a single patient. The output leads to optimal, near-optimal, clinically acceptable or even non-acceptable treatment plans. In this thesis, the possibility of using machine and deep learning to minimize the amount of treatment plans generated by the autoplanning software as well as the possibility of finding cost function parameters that lead to clinically acceptable optimal or near-optimal plans is evaluated. Data augmentation is used to create matrices of optimal treatment plan parameters, which are stored in a training database. Patient specific training features are extracted from the TPS, as well as from the bottleneck layer of a trained deep neural network autoencoder. The training features are then matched against the same features extracted for test patients, using a k-nearest neighbor algorithm. Finally, treatment plans for a new patient are generated using the output plan parameter matrices of its nearest neighbors. This allows for a reduction in computation time as well as for finding suitable cost function parameters for a new patient. Machine Learning Deep Learning Data Augmentation Treatment Planning External Beam Radiation Therapy Elektroteknik och elektronik
9	Friction, wear and mechanical properties of electron beam modified PTFE-based rubber compounds Khan, Mohammad 24 April 2009 (has links) (PDF) Die inhärenten elastomeren Eigenschaften von Gummiwerkstoffen sind im Vergleich zu Thermoplasten in vielen Spezialanwendungen vorteilhaft. Jedoch sind ihre schlechten Reibungs- und Verschleißeigenschaften ein wesentlicher Nachteil besonders bei tribologischen Anwendungen. In der vorliegenden Arbeit wurden Reibung, Verschleiß und mechanische Eigenschaften von Gummiwerkstoffen, die Polytetrafluorethylen(PFTE)-Pulver enthalten, untersucht. Hauptziel war dabei die Verbesserung der Reibungs- und Verschleißeigenschaften bei weiterer Erhöhung der mechanischen Eigenschaften der Elastomere. Es ist bekannt, dass sich Reibungs- und Verschleißeigenschaften gummiähnlicher Materialien in vielfältiger Weise von den Reibungseigenschaften der meisten anderen Festkörper unterscheiden. Die Gründe dafür sind das viskoelastische Verhalten und der sehr geringe elastische Modul von Gummi. Die Verwendung von mit Elektronen modifizierten PTFE-Pulvern in Ethylen-Propylen-Dien-Monomer (EPDM) Kautschuken führt zu einer signifikanten Reduzierung der Reibung, Erhöhung der Verschleißfestigkeit und gleichzeitig zu verbesserten mechanischen Eigenschaften in Folge einer speziellen chemischen Kopplung zwischen dem modifiziertem PTFE-Pulver und dem EPDM. Gummirezeptur, Vernetzungsmethode und die viskoelastischen Materialeigenschaften beeinflussen wesentlich die tribologischen und mechanischen Eigenschaften. Morphologie, Dispersion und die chemische Kopplung des PTFE-Pulvers haben einen signifikanten Einfluss auf die Reibungs- und Verschleißverhalten. Die viskoelastischen Materialeigenschaften, d.h. Härte, E-Modul und tan delta (Verlustfaktor) der Gummimischungen sind kritische Parameter und erfordern deshalb eine Optimierung. In dieser Arbeit wurden zwei Modellsysteme untersucht, die auf zwei unterschiedlichen Kautschuktypen basieren: a) Ethylen-Propylene-Diene-Monomer (EPDM) Kautschuk und b) Polychloropren Kautschuk (CR). / The inherent elastomeric properties of rubber compounds in comparison to thermoplastics are advantageous in many special purpose applications. However, their characteristic poor friction and wear properties are of prime concern especially in tribological applications. In the present work, friction, wear and mechanical properties of rubber compounds based on PTFE powder have been investigated. The main aim was to improve the friction and wear properties while further enhancing the mechanical properties of rubber compounds. As known, friction and wear behaviour of rubber-like materials differ in many ways from the frictional properties of most other solids. The reason for this is the high viscoelasticity and very low elastic modulus of rubber. The use of electron-modified PTFE powder in EPDM results in significant improvement in reducing friction, enhancing wear resistance and simultaneously improving mechanical properties due to specific chemical coupling between modified PTFE powder and EPDM. The rubber formulation, crosslinking mode and bulk viscoelastic properties strongly influences friction, wear and mechanical properties. The morphology, dispersion, and specific chemical coupling of PTFE powder play a significant role on friction and wear behaviour. The bulk viscoelastic properties, i.e. hardness, modulus and tan delta (loss factor) of the compounds are critical parameters and therefore, requires optimization. In this work two model systems based on two different rubber matrixes i.e. Ethylene-Propylene-Diene-Monomer (EPDM) and Chloroprene (CR) rubber have been investigated. PTFE Elastomers Electron beam radiation Friction Wear Mechanical properties PTFE Elastomere Elektronenbestrahlung Reibung Verschleiß Mechanischen Eigenschaften ddc:610 rvk:ZM 5300
10	Estudo comparativo dos parâmetros associados à dose absorvida e controle de qualidade em aceleradores lineares com filtro aplainador (FF) e sem filtro aplainador (FFF) / Comparative study of the parameters associated with quality control and absorbed dose in linear accelerators with (FF) and without (FFF) flattening filter SOUZA, ANDERSON S. de 17 November 2017 (has links) Submitted by Pedro Silva Filho (pfsilva@ipen.br) on 2017-11-17T17:35:26Z No. of bitstreams: 0 / Made available in DSpace on 2017-11-17T17:35:26Z (GMT). No. of bitstreams: 0 / A utilização da técnica de teleterapia para tratamento de câncer tem sido usada por anos com bons resultados clínicos. Em meados da década de 90, a remoção do filtro aplainador, item que compõe o cabeçote de um acelerador linear de uso clínico, tem sido objeto de estudos por demonstrar bons resultados no tratamento de alguns tipos de câncer. Técnicas utilizadas como Radioterapia de Intensidade Modulada (IMRT) e Radioterapia Estereotáxica (SRT), mostram-se mais eficazes quando não se utiliza o filtro aplainador. A empresa Varian Oncology lançou em 2012 um acelerador linear de uso clínico capaz de operar com o filtro aplainador (FF) e sem o filtro aplainador (FFF), o TrueBeam. Os objetivos desse trabalho são avaliar a homogeneidade de dois importantes parâmetros utilizados para o cálculo de dose nos pacientes submetidos ao tratamento com esse modelo de acelerador linear, a porcentagem de dose profunda (PDP) e índice de qualidade do feixe (TPR20/10). Os dados fornecidos para a análise foram cedidos pelo Hospital Israelita Albert Einstein (HIAE), Real Hospital Português (RHP) e 3 instituições norte-americanas. Através de uma análise estatística dos dados das instituições citadas pode-se observar melhor o comportamento desses parâmetro que demonstraram-se muito homogêneos e com erros menores que 1% na maioria dos casos, confirmando desse modo que os aceleradores lineares do modelo TrueBeam mantém na maioria das vezes uma boa concordância dos parâmetros analisados. / Dissertação (Mestrado em Tecnologia Nuclear) / IPEN/D / Instituto de Pesquisas Energéticas e Nucleares - IPEN-CNEN/SP linear accelerators radiotherapy x radiation external beam radiation therapy filters cones absorbed dose range absorbed radiation doses comparative evaluations

Search results