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71	Characterization of neutron detection efficiency in a liquid organic scintillator Wargh, Ebba, Tabeshnia, Nadine January 2023 (has links) Neutron detectors in the form of liquid organic scintillators are widely used for nuclear disarmament purposes. The main purpose of this thesis is to characterize the neutron detection efficiency of the organic liquid scintillator EJ-309 using Monte Carlo based simulations in the simulation program Geant4. The Monte Carlo simulation code was benchmarked using recorded light output data from a laboratory experiment and it was confirmed that the simulation code could reproduce data from this experiment. In order to characterize the efficiency of the neutron detector, the benchmarked code was used to simulate light output distributions of 241-Am-Be and Cf-252, an (α, n) and a spontaneous fission source respectively, where it was found that the two different types of sources could be distinguished. However, distinguishment between two different spontaneous fission sources was not possible, as simulations of the light output distribution of another spontaneous fission source, Pu-240, was similar to the one for Cf-252. The light output distributions from the simulations were compared to earlier research where good agreements were obtained. A quantitative study was also performed to determine how many detected neutrons were needed to properly be able to distinguish between the two sources 241-Am-Be and Cf-252, and the number was found to be 560. This value was considered low relative to the number of detected neutrons in the simulations, and hence, more quantitative studies are needed in order to verify this result. The absolute and intrinsic detection efficiency were also determined for varying threshold values of neutron energy. Other Physics Topics Annan fysik
72	Propagation of Nuclear Data Uncertainties for Reactor Physics Parameters in Fluorine-19-based Molten Salt Reactors Stjärnholm, Sigfrid January 2023 (has links) It could be argued that a renaissance is taking place for the global interest in nuclear power - especially for the development of the next generation of reactor systems that aim at solving the problems with contemporary energy production with nuclear technology. One such proposed concept for Gen IV nuclear power is a Molten Salt Reactor (MSR), in which the nuclear fuel is in solution of a salt - often based on fluorine or chlorine. The historical experience of MSRs is limited in both scope and time, but significant developments have been made in the past few years. In order for such technologies to become commercially viable, it is important that investigations are conducted into the behaviour of the materials involved. In this work, the propagation of uncertainty in nuclear data for the isotope F-19 is investigated in a fluorine-based MSR. Uncertainty quantification is important in reactor physics as calculations that are based on Best Estimate Plus Uncertainty often leave more margin to the regulatory requirements compared to conservative calculations. The quantity of interest is the reactivity of the system at hand, and three different levels of moderation were investigated in order to observe any differences that the hardness of the neutron spectrum might impose on the reactivity uncertainty. In addition, the individual neutron-nucleus interaction channels are analyzed separately in order to deduce which channels that contribute the most to the reactivity uncertainty. The nuclear reactor cores were simu- lated with the Monte Carlo-based neutron transport code OpenMC, and the uncertainty quantification was performed using the Total Monte Carlo (TMC) methodology with perturbed nuclear data that was generated using the tools SANDY and NJOY. The results from the uncertainty quantification showed that the nuclear data uncertainty from F-19 gave rise to reactivity uncertainties of approximately 60-200 pcm, depending on the amount of moderation rods that were inserted. The less moderated systems were more susceptible to the F-19 uncertainties, which could be explained by the fact that those systems gave more room for the fluorine- based fuel, and hence they would be more exposed to the uncertainties of F-19. It was also observed that the elastic scattering, neutron capture, and alpha production reaction channels contributed the most to the uncertainties in the most moderated reactor, while the least moderated reactor was most susceptible to the uncertainties due to elastic scattering, inelastic scattering, and alpha production. These findings show that significant improvements needs to be made in the measurements and evaluations of nuclear data for F-19 if it is to be implemented in MSRs of the future. / Intresset för kärnkraft har under de senaste åren utvecklats enormt globalt - särskilt med avseende på utveckling av nästa generation av reaktorsystem som har målen att lösa de problem som finns med dagens energiproduktion via kärnteknik. Ett sådant föreslaget koncept för Fjärde generationens kärnkraft är saltsmältereaktorn (eng. Molten Salt Reactor, MSR), i vilket kärnbränslet är upplöst i reaktorn i ett salt som oftast är baserat på fluor eller klor. Den historiska erfarenheten av MSR:er är knapphändig, men stora framsteg har gjorts under de senaste åren. För att tekniker som denna ska kunna blir kommersiellt genomförbara måste utredningar göras för att förstå hur exempelvis det använda materialet beter sig. I detta arbete propageras osäkerheterna i kärndata för isotopen F-19 genom en fluor-baserad MSR. Os- äkerhetskvantifiering är viktigt i reaktorfysik eftersom beräkningar som är baserade på Bästa Uppskat- tning Plus Osäkerhet (eng. Best Estimate Plus Uncertainty, BEPU) oftast lämnar en större marginal till regulatoriska begräsningar än vad konservativa beräkningar gör. Storheten av intresse i detta ar- bete är reaktiviteten av reaktorhärden, och tre olika nivåer på moderering användes för att kunna observera skillnader i reaktivitetsosäkerheter som orsakas av neutronspektrumets hårdhet. Dessutom undersöktes de individuella reaktionskanalerna för neutron-kärna-interaktioner för att kunna dra en slutsats kring vilka reaktionskanaler som bidrar mest till reaktivitetsosäkerheterna. Reaktorhärdarna simulerades med den Monte Carlo-baserade neutrontransportkoden OpenMC, och osäkerhetskvanti- fieringen gjordes genom Total Monte Carlo (TMC) metodologin med kärndata som genererades med verktygen SANDY och NJOY. Resultaten från osäkerhetskvantifieringen visade att kärndataosäkerheterna från F-19 gav upphov till reaktivitetsosäkerheter på ungefär 60-200 pcm, beroende på vilken modereringsgrad som användes. De mindre modererade systemen var mer mottagliga till osäkerheten hos F-19, vilket skulle kunna förklaras genom att dessa system gav mer plats för det fluor-baserade bränslet, vilket därmed leder till att de är exponerade till osäkerheterna för F-19 i en högre grad. Det observerades också att reaktionskanalerna elastisk spridning, neutroninfång samt alfa-produktion hade stört inverkan på reaktivitetsosäkerheterna för de mest modererade systemen, medan de minst modererade systemen var mer mottagliga till osäkerheterna som orsakades av elastisk spridning, inelastisk spridning och alfa-produktion. Dessa resultat visar att förbättringar måste göras i mätningarna samt evalueringarna av kärndata för F-19 om ämnet ska implementeras i MSR:er i framtiden. Other Physics Topics Annan fysik
73	Classical motion in synthetic monopole fields Carlsson, Ola January 2022 (has links) In the Born-Oppenheimer approximation for a quantum system the emergent synthetic magnetic field can be seen as generated by monopoles at points of degeneracy, in full analogue to the synthetic fields generating the geometric phase of adiabatically evolving quantum systems. The plausibility of using these synthetic magnetic monopoles as a means to study magnetic monopole dynamics in the absence of fundamental magnetic monopoles has been explored. A bipartite spin system consisting of a dumbbell translating and rotating through space has been modelled, and full equations of motion in the presence of an external magnetic field have been derived. A collection of scripts for numerical evaluation of these equations of motion were subsequently developed, and further put to use in sample simulations for a small range of parameters. The results demonstrate non-negligible perturbations to the centre of mass motion when compared to motion not considering the Born-Oppenheimer synthetic fields, for dumbbell masses of small but not unrealistic proportions. The problems inherent in this approach to elucidating motion in magnetic monopole fields are discussed, but the method should not yet be dismissed until further investigations have been made. / Under Born-Oppenheimer-approximationen för ett kvantsystem kan det emergenta syntetiska magnetfältet ses som alstrat av monopoler vid degenerationspunkter, helt analogt med de syntetiska fält som genererar den geometriska fasen vid adiabatisk utveckling av kvantsystem. Möjligheten att använda dessa syntetiska magnetiska monopoler för att studera dynamiken från verkan av en magnetisk monopol, trots att fundamentala magnetiska monopoler ej observerats, har utforskats. Ett tvådelat spinsystem beståendes av en hantel som translaterar och roterar genom rummet har modellerats, och fullständiga rörelseekvationer i närvaron av ett yttre magnetfält har härletts. Kod till ändamålet att utvärdera dessa rörelseekvationer har därpå utvecklats, och vidare nyttjats för att simulera rörelsen för ett stickprov av parametrar. Resultaten visar på ej försumbara perturbationer av masscentrums rörelse vid jämförelse med rörelse utan hänsyn till de syntetiska Born-Oppenheimer-fälten, för hantlar av liten men inte orealistiskt liten massa. Problemen och komplikationerna för det här angreppssättet till att utforska rörelse genom magnetiska monopolers fält diskuteras, men metoden bör ej ännu avvisas innan vidare undersökning har genomförts. Other Physics Topics Annan fysik
74	Studies on Reverse Engineering of Constant Frequence Geometric Quantum Gates Zijin, Wu January 2022 (has links) Geometric Quantum Computation (GQC) is one of the effective methods to realizequantum computation. By using geometric phases, it shows robustness to certainerrors. This thesis aims to develop a new systematic technique for implementing GQC,especially in non-adiabatic systems. First, we examine the nature of the geometric phasewith differential geometry. Then, we give a general theoretical method to realize a givenquantum gate with a geometric phase through reverse engineering. We examine themethod in the constant frequency quantum system with 2 or 3 energy levels. Finally, weanalyze the non-Abelian case where some of the frequencies are degenerate. / Geometrisk kvantberäkning (GQC) är en av de effektiva metoderna för att förverkligakvantberäkningar. Genom att använda geometriska faser visar den sig vara robustmot vissa fel. Syftet med denna avhandling är att utveckla en ny systematisk teknikför att genomföra GQC, särskilt i icke-adiabatiska system. Först undersöker vi dengeometriska fasens natur. med hjälp av differentiell geometri. Därefter ger vi en allmänteoretisk metod för att realisera en given kvantgrind med en geometrisk fas genomreverse engineering. Vi undersöker metoden i kvantsystemet med konstant frekvensoch med 2 eller 3 energinivåer. Slutligen analyserar vi det icke-Abeliska fallet där vissaav frekvenserna är degenererade. Other Physics Topics Annan fysik
75	Modeling wave behavior with linear wave theory Renström, Elsa January 2024 (has links) This thesis aimed to look at the behaviours of the water beneath waves from a modeling and simulations point of view. We have investigated how to use Linear wave theory (LWT) to model the kinematic movements in water governed by free ocean waves. The model assumes the surface to consist of a superposition of sinusoidal waves. We have used fast Fourier transform (FFT) to move the surface waves from the space domain to the frequency domain from which we used the components to transform back with the inverses described by LWT. We recreated the surface with the expression for surface elevation for both two and three dimensions, and compared to the original surface. Then the same transformed components could be used to calculate the velocity fields beneath the surface. We found that the recreated surface aligns with the original surface in two and three dimensions. For the three dimensional surface we also found that the error is larger on the peaks of the waves and that at the boundary where the surface ends the error is significant due to some implementation error which we disregard. The calculated velocity fields has the expected circular movement over time and it decreases with depth. We found that a surface described with few discrete points significantly overestimates the velocities close to the surface. By increasing the number of points on the surface with simple linear interpolation this issue was resolved. The algorithms used to calculated the inverse transforms had complexity Ο(N) where N is the number of points for which to calculate the velocity, and the FFT has complexity Ο(N log N) where N is the amount of points that the surface consists of. The performance test seems to follow this trend. For applications of the methodology some future work is advised. Firstly the velocities need to be compared to some data to validate the method. Secondly some further time needs to be spent on the three dimensional case to verify that that the velocity fields behave properly and that the cross sections match with the two dimensional case. And finally, we apprehended an issue on which wavenumber to use for each wave component. Since the positive and negative wavenumber is possible and determines the propagation direction of that wave, we need to find a way to make sure that we are using the correct one for each wave component of an unknown surface. Other Physics Topics Annan fysik
76	Growth and characterization of thin EUROFER97 films Fernández Pascual, Carlos January 2022 (has links) No description available. Other Physics Topics Annan fysik
77	Surface characterization and force measurements applied to industrial materials with atomic force microscopy Dobryden, Illia January 2012 (has links) The thesis focuses on the application of force measurements with atomic force microscopy (AFM) on materials with a few surface contacts/asperities and chemically modified surfaces. The technique allows measurements of ultra-small intermolecular and surface forces, down to the piconewton level. The force measurements between surfaces of well-defined geometry are often used to measure and model the interaction between different systems of charged and neutral surfaces in various environments. However, detailed knowledge of the contacting surface profile geometry and surface properties is required to model the fundamental forces involved in the interaction. The preparation of such well-defined and idealized surfaces is often time consuming and the surfaces may not possess the behavior and properties of a source material in real processes, such as in industry. Moreover, external factors such as magnetic fields, ionic strengths and pH-values in a solution, may further complicate the evaluation. Hence, it is desirable to explore and develop techniques for trustable measurements of forces between “real” surfaces. These are often a complex composition of various force interactions and multiple surface contacts.The AFM probe technique was explored to measure force interactions between “real” particle surfaces. The work shows the applicability of the AFM technique to study the interaction forces despite the forecasted difficulties with the roughness of the particles.A technique to measure the adhesion and work of adhesion from AFM force curves was implemented and used. The thermal tune method was implemented in our commercial NT-MDT microscope to determine cantilever spring constants. The force interactions between natural microsize (m-s) magnetite particles and synthetic nanosize (n-s) magnetite particles were studied in calcium solution with concentrations of 1, 10, 100 mM and at pH values 4, 6 and 10. The changes in force interactions, due to variations in calcium concentration and pH were investigated. The adhesion force change with the concentration and pH was similar for m-s/m-s and m-s/n-s systems, and the adhesion force increased with the concentration at pH 6, except for the highest calcium concentration of 100 mM at pH 10. It was found that the magnetite surface modification could appear at the highest calcium concentration at pH 10. Moreover, the thesis contains preliminary results of the force interaction study between natural and synthetic bentonite-magnetite particles in calcium solution with concentrations of 1, 10 and 100 mM at pH 6.The influence of roughness on the calculation of contact mechanics parameters were studied with AFM and Vertical Scanning Interferometry (VSI). This is important for future development of a model to describe and characterize the force interaction between samples with multiple surface contacts. It was found that the optical artifacts, induced by VSI, have a large influence on all the roughness parameters calculated on the calibration grids, which represent extreme surface topographies. Other Physics Topics Annan fysik
78	Laser induced effects in carbon nanotubes : implications for Raman characterization of functionalized systems Olevik, David January 2009 (has links) Carbon nanotubes (CNTs) have attracted attention over the past decade because of their outstanding mechanical and electronic properties. These tiny tubular shells made of carbon atoms can be metallic or semiconducting and while having diameters of only about one nanometer (10-9 m), they can be up to centimeters in length, making them quasi one-dimensional (molecular wires). Along with a Young's modulus several times that of steel, CNTs are close to perfect (ballistic) electric conductors and conduct heat better than diamond. This makes them candidates for a variety of applications from nanoscale electronics and composites reinforced with CNTs on the molecular level to nano-actuators and high performance flatscreen displays.Beside electron microscopy, no other experimental method has been employed more in research on carbon nanotubes than Raman spectroscopy since it can noninvasively probe single CNTs and provide direct information about their molecular properties, for example, diameter and chirality. That is possible because in the case of CNTs Raman scattering is resonantly enhanced, giving an increase in signal by a factor of 106. Due to their high surface energy and the van der Waals inter-tube interactions, carbon nanotubes naturally form bundles of up to hundreds of tubes. Heat dissipation in CNT bundles is inefficient and, as a result, their exposure to high incident laser power causes overheating and results in several thermal effects dominating the Raman spectrum. The high cost of CNT production has strongly impeded design of "pure nanotube" functional materials, thus shifting the focus of CNT materials research to creation of CNT-based composites. Such new multifunctional materials, based on the outstanding physical properties of nanotubes, are created by mixing relatively small amounts of CNTs with polymers or metals (matrix). This is still a big challenge because of poor dispersion of CNT bundles in the matrix and weak bonding of the nanotubes to the surrounding host (matrix) molecules. One proposed solution to solve the latter problem is to establish bonding of CNTs to the matrix via functional groups covalently attached to the CNT surface, i.e., to use so-called "functionalized" CNTs in composites.The aim of this work is to explore the possibilities of using Raman spectroscopy for expressive characterization of functionalized CNTs, the source material for synthesis of CNT-based composites. CNTs produced by two synthesis techniques, with different diameter distributions, were probed using several laser excitations. Evaluating the efficiency of the functionalization process requires first determination of the intrinsic spectroscopic properties of the pristine (non-functionalized) CNTs. Because functionalization is carried out on bundled CNTs, a detailed investigation of whether the incident laser irradiation causes thermal effects in the sample during Raman experiments was performed in order to find experimental protocols for recording the intrinsic (unperturbed by heating) spectrum of the CNT bundles. From this study a set of "reference conditions" defining laser irradiance levels that do not result in overheating of the CNT bundles was established. Exceeding these laser irradiation levels (thresholds) first results in reversible changes of the Raman spectrum due to heating, while further increase of the laser irradiation leads to irreversible changes in the spectra and, hence, destruction of the CNTs in the sample. Evaluation of this destruction demonstrates its dependence on CNT diameter and high sensitivity to photon energy. Additional experiments show that in some cases a similar instability of the Raman spectra and irreversible destruction of the CNTs occur at laser irradiation levels below those that increase sample temperature. Finally, we used the "reference" laser irradiation regimes to characterize the effects of CNT sidewall functionalization. Specifically, HiPCO-produced, single-walled CNTs functionalized by methoxypenyl functional groups were studied in detail and the influence on the three main vibrational bands investigated. Results from analysis of the radial breathing mode band show that the functionalization process is selective and depends on both nanotube diameter and type. Other Physics Topics Annan fysik
79	A spectroscopic study of polymer : Carbon nanotube composites Müller, Andreas January 2011 (has links) Since the identification of carbon nanotubes (CNTs) by Ijima in 1991, this material has become a subject of great interest and effort in science because of the outstanding physical properties it exhibits. CNTs can be thought of as graphene sheets rolled into seamless cylinders of various diameters and in principle infinite length. Depending on the number of concentrically arranged tubes, CNTs are termed single‐walled (SWCNT), double‐walled (DWCNT), and multi‐walled (MWCNT) CNTs. Moreover SWCNTs exist as semiconducting or metallic types, depending on the orientation of the hexagonal lattice relative to the tube axis, as classified by the chiral indices (n, m). Their extraordinary mechanical, electrical, thermal, and optical properties render them very attractive for a wide range of applications including advanced composite materials. However synthesis of CNT‐based composite materials still remains a big challenge. In particular it remains to overcome the difficulties in achieving good nanotubes dispersion within the matrix material. The fact that present synthesis routes produce SWCNTs in a bundled state due to van der Waals intertube interaction is another serious hurdle, as SWCNT bundles do not exhibit the excellent properties of their individual components. Thus special treatment has to be applied in order to break these bundles. In an ideal composite material, the individual SWCNTs would be homogeneously dispersed in the matrix. A second issue is the interaction between the CNTs and the host: to improve the load transfer between host and filler covalent linking between the two components is desirable. One approach to solve these problems is functionalization of the CNT source material prior to its incorporation into the polymer matrix. Optimization is required to maximize the transfer from the polymer to the CNTs but minimize the number of wall defects created by the covalent grafting of the functional groups on the CNT sidewalls. Moreover appropriate functional groups have to be chosen to assure compatibility with the polymer being used. Synthesis of the polymethyl methacrylate (PMMA) composite material used here, based on functionalized SWCNTs, was reported recently and its study revealed inhomogeneities in the CNT distribution within the polymer and associated degradation in the mechanical properties suggested as being attributed to the presence of CNT agglomerates. Since Raman spectroscopy, as a mostly non‐destructive analysis method, has proven to be a powerful tool for studying both pure CNT materials and CNT‐based composites, it was used in this work along with supporting methods (scanning electron microscopy (SEM) and focused ion beam (FIB)) for extended characterization of the composite material, including analysis of the source SWCNT material before and after functionalization. Employment of different laser excitation energies (1.96eV and 2.33eV) allowed to separately probe metallic and semiconducting CNTs in the composite samples. The CNT distribution in the samples was illustrated by Raman spectral mapping of the G+‐ peak intensity as a function of position, thus elucidating the presence of CNT agglomerates of different size and shape. At both photon energies, spectral line scans across the boundary regions were performed revealing a substantial drop in intensity of G+ CNT Raman mode and an increase of the D/G+‐intensity ratio. Examination of the D/G+‐ intensity ratio of the SWCNT material before incorporation into the composite showed a higher value for functionalized than for the raw SWCNTs. Furthermore, the metallic nanotubes exhibited a higher degree of functionalization. Raman spectral imaging revealed some inhomogeneities of the CNT distribution in the composite material: the spectra of the areas with good CNT dispersion in the composite exhibit a higher D/G+‐ intensity ratio than in areas with CNT agglomerates indicating that functionalized CNTs are preferentially dispersed in the polymer matrix while non functionalized ones tend to group together in agglomerates. Furthermore significant laser heating of the SWCNTs in composites has been revealed resulting in a downshift of the G+‐ peak position which was much more pronounced in agglomerates than in the areas with dispersed CNTs and detected at the very lowest laser irradiances. SEM/FIB dual beam technique was employed as a supplementary analysis tool. The composites microstructure in CNT agglomerates as well as in the dispersed area was investigated by acquisition of SEM crossectional images confirming the different local CNT concentrations. Other Physics Topics Annan fysik
80	Nanostructured carbon materials under extreme conditions Mases, Mattias January 2012 (has links) No description available. Other Physics Topics Annan fysik

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