"Aplicação da radiação por feixe de elétrons como agente esterilizante de microorganismos em substrato turfoso" / APPLICATION OF ELECTRON BEAM RADIATION FOR PEAT STERILIZATION AND SUPPRESSION OF MICROBE CONTAMINANTS

David Tsai

23 June 2006

A inoculação de sementes de leguminosas de grãos tais como soja [Glycine max. (L.)], feijão (Phaseolus vulgaris L.) e pastagens tem sido uma estratégia efetiva e conveniente para introduzir estirpes eficientes de Bradyrhizobium/Rhizobium em solos agrícolas sem histórico de cultivo anterior dessa cultura ou quando as estirpes ivas são ineficientes no processo biológico de aquisição de nitrogênio. Através do uso de substrato turfoso previamente esterilizado como veículo da bactéria, os efeitos ambientais adversos podem ser amenizados, pois este substrato atua diretamente, na sobrevivência da bactéria através do fornecimento de nutrientes. O Brasil requer que os substratos turfosos sejam pré-esterilizados através de radiação gama de cobalto-60 (60Co), sendo recomendada a dose de 50 kGy para uma efetiva eliminação de patógenos e saprófitas, que podem competir com a bactéria introduzida. Recentemente, a utilização de aceleradores de elétrons foi considerada uma nova alternativa de radiação para pré-esterilização da turfa, pois, por se constituir de processo oxidativo avançado, gera radicais altamente reativos, eficientes na eliminação de agentes contaminantes. Esta técnica é considerada ecologicamente mais segura que a radiação gama, além de ser um processo mais rápido. Há, porém, a característica de ter menor profundidade de penetração da radiação em relação ao 60Co. O presente estudo comparou o método usando doses crescentes de radiação gama por 60Co e por feixe de elétrons (0, 10, 20, 30, 40 e 50 kGy). Os dados experimentais (7, 14, 21 e 28 dias para a fase curta e 150, 180 e 210 dias para a fase longa de incubação) mostraram um elevado número de células da bactéria Rhizobium tropici CM-01 gusA+ inoculada em substratos turfosos submetidos aos dois processos de esterilização, sendo que ambos processos atenderam aos padrões mínimos requeridos pelas normas brasileiras (validade de 180 dias e presença acima de 1 x 108 células/g de substrato). Sob doses mais elevadas, acima de 40 kGy, o método por feixe de elétrons foi mais eficiente em eliminar actinobactérias, consideradas sérias antagonistas de bactérias inoculantes em turfas e que surgiram após 150 dias. Em um segundo estudo, usando o isolado CM-01 celB+ por um período de 30 dias, os resultados confirmaram a eficiência do método por feixe de elétrons na fase de crescimento bacteriano, mesmo para dose baixa de 10 kGy. / Inoculation of root nodule bacteria into legume seeds such as soybean [Glycine max. (L.)], common bean (Phaseolus vulgaris L.) and forrage pasture has been effective and convenient as this simple procedure may introduce effective strains of Bradyrhizobium/Rhizobium into agricultural soils without a past history of successful cropping systems with the legume hosts. Peat-based substrates previously sterilized have been used for decades as bacteria carrier, protecting them from the prevailing harsh conditions in tropical soils and ensuring their survival with nutrient and protection against the soil antagonists. The Brazilian Government requires that all peat-based substrates must be gamma-sterilized from a cobalt-60 (60Co) source, prior the introduction of the root nodule bacteria into the package. The recommendation is for a dose up to 50 kGy for an effective suppression of pathogens and saprophytes, in order to avoid competition among the substrate microbiota. Recently, the use of the electron beam (EB) accelerator has shown to be a new alternative for peat pre-sterilization, as this technique may promote reactive free-radicals which are efficient to suppress microbial contaminants. This fast technology is considered more environment and ecology friendly-sound than gamma radiation (γ). The disvantage of not reaching higher depth than gamma rays from 60Co must be considered, and attempts of optimizing the technique are crucial. This study compared both methods by using increasing rates of radiation by 60Co by the EB method - 0, 10, 20, 30, 40 e 50 kGy in a commercial peat used for inoculants. Experimental data from days 7, 14, 21 and 28 days (growth period) and 150, 180 and 210 days (storage period) indicated high numbers of the strain Rhizobium tropici CM-01, labelled with gusA+ (Study 1) and celB+ (Study 2) from both eat-sterilizing techniques, reaching values above the minimum of 1x108 cells g-1 peat. At high rates, above 40 kGy, and after long incubation periods (ex. after 150 days), EB method was more efficient to suppress actinobacteria, one serious antagonist for rhizobia. Strain CM-01 celB+, data for the period of bacterial growth confirmed the efficiency of the method even at rates as low as 10 kGy.

feixe de eletrons

irradiacao

turfa

electron beam

radiation

turf

Applications of optical manipulation for low cost implementation, beam shaping and biophysical force measurements

McDonald, Craig

January 2017

There are a growing variety of research fields requiring non-contact micro- manipulation. An increasing number of these fields are turning to optical tweezers as a solution, owing to their high spatial and temporal resolution. Optical tweezers have the ability to quantitively exert and measure forces on the piconewton scale, a convenient force scale for soft biological materials, and are hugely versatile due to the wide assortment of beam shaping techniques that can be employed. The work in this thesis can be broadly divided into two main themes: that quantifying the optical trapping forces in shaped beams; and bringing control and simplification of complex systems to non-expert users who may utilise optical tweezers as part of interdisciplinary collaborations. Static beam shaping is used to generate a conically refracted optical trap and the trapping properties are characterised. It is shown that trapping in the lower Raman spot gives full, 3D gradient trapping, while the upper Raman spot allows for particle guiding due to its levitation properties. Particles in the Lloyd/Poggendorff rings experience a lower trap stiffness than particles in the lower Raman spot but benefit from rotational control. Dynamic beam shaping techniques are exploited for the simplification of complex systems through the development and testing of the HoloHands program. This software allows a holographic optical tweezers experiment to be controlled by gestures that are detected by a Microsoft Kinect. Multiple particle manipulation is demonstrated, as well as a calibration of the tweezers system. Application of trapping forces is demonstrated through an examination of integrin – ligand bond strength. Both wild type effector T cells and those with a kindlin-3 binding site mutation similar to that found in neutrophils from Leukocyte Adhesion Deficiency sufferers are investigated. Through the use of back focal plane interferometry, a bond rupture force of (17.9 ± 0.6) pN at a force loading rate of (30 ± 4) pN/s, was measured for single integrins expressed on wild type cells. As expected, a significant drop in rupture force of bonds was found for mutated cells, with a measured rupture force of (10.1 ± 0.9) pN at the same pulling rate. Therefore, kindlin-3 binding to the cytoplasmic tail of the β2-tail directly affects bond strength of single integrin-ligand bonds. An experimental system for studying these cells under more physiologically relevant conditions is also presented. Additionally, a low-cost optical micromanipulation system that makes use of simple microfabricated components coupled to a smartphone camera for imaging is proposed and demonstrated. Through the layering of hanging droplets of polydimethylsiloxane (PDMS) on microscope coverslips, lenses capable of optical trapping are created. Combination of PDMS with Sudan II dye led to the fabrication of long pass filters. An extension of this low-cost system into the life sciences is proposed through the adaptive use of bubble wrap, which allows for the culturing of cells in a chamber compatible with optical trapping.

621.36

Octupole and quadrupole structures in the N=88 nucleus 152Gd

Netshiya, Adivhaho Andrew

January 2018

>Magister Scientiae - MSc / The focus for this work is on 152Gd produced by the 150Sm( , 2n)152Gd reaction at a beam energy of 25 MeV. The nucleus has been previously studied for both low spin states and high spin states at di erent energies. The most recent work on 152Gd was done by S. P. Bvumbi using the 152Sm( , 4n)152Gd reaction at a beam energy of 45 MeV where she was able to populate low spin states and assign spins and parities to the levels as shown in Fig. 1.1. The nucleus 152Gd, with proton number Z=64 subshell closure, belongs to a set of isotones having N=88 in the transitional region with just 6 neutrons outside the N=82 closed shell and lies just before the N=90 permanently deformed region. The isotope 152Gd is in the transitional region, consequently its nuclear collective motion will quickly evolve from vibrational to rotational motion. The low lying K =0+2 bands in N=88 and 90 nuclei appear at low excitation energies and are poorly understood. Key to these studies is the crucial question about the legitimacy of the low lying K =0+2 bands being described as vibrations along the symmetry axis. The current work examines the K =0+2 band with the objective of providing more understanding. Previous studies of N=88 isotones saw consistent E1 transitions both from and to the K =0+2 bands and octupole bands, namely 144Ba, 146Ce, 148Nd, 150Sm and 154Dy nuclei. The experimental systematics of the low lying negative parity states in N=88 isotones are remarkably well reproduced by theoretical calculations of the quadrupole octupole coupling (QOC) modelas shown in Fig. 1.2.

Beam energy

High spin

Low spin

Energies

Nucleus

Ultraviolet sources for advanced applications in the vacuum UV and near UV

Peng, Sheng

01 January 2004

This dissertation documents a systematic study consisting of experimental investigations and theoretical analyses of intense ultraviolet sources in VUV and near-UV. Some engineering issues regarding two prototypes of electrodeless lamps using rf and microwave are discussed.;Various excimers that produce intense UV light are investigated, including: (1) A benchmark Xe2 excimer which has been proven to be very efficient in our novel rf capacitively coupled discharge lamp; (2) A rarely studied excimer, KrI, which suffers from predissociation and was reported to be very weak or invisible by most of other studies; (3) XeI excimer whose emission dominates around 253 nm and is promising as a mercury-free lamp for antibacterial applications. In the above studies, discharge temperatures are estimated from the emission band width. An elaborate kinetic model is developed for KrI to account for the KrI* and I2* intensities as a function of pressure. It was found that Kr2* plays the rule for energy transfer instead of Kr* in the pressure of interest. The electromagnetic wave interaction with charge particles is studied in our 2D and 3D EM-PIC simulations for both the rf and microwave lamps. Important plasma parameters, such as the electron density and temperature are obtained for various pressures. The electron energy distribution function that is important to account for excimer excitation is obtained.;We also performed a high-level ab initio calculation in Gaussian to produce the ground state potential curve for KrI, which agrees with previous scattering experiments and is necessary for predicting spectral emissions. as a systematic study to account for the KrI emission spectra at high pressure, we use a semiclassical model to account for emissions between a bound excited state and an unbound ground state. An explicit expression is obtained to represent the observed spectral intensity. Important molecular constants are obtained for KrI and compared with previous results.

Atomic, Molecular and Optical Physics

Nuclear

Plasma and Beam Physics

Early phase of the cross car beam concept development

Silva, Ana Rita Cunha Rodrigues da

January 2013

Tese de Mestrado Integrado. Engenharia Mecânica. Faculdade de Engenharia. Universidade do Porto. 2013

Design e desenvolvimento do produto

Indústria automóvel

Cross Car Beam

Processo sistemático

Fast Operator Splitting Methods For Nonlinear Pdes

January 2016

Operator splitting methods have been applied to nonlinear partial differential equations that involve operators of different nature. The main idea of these methods is to decompose a complex equation into simpler sub-equations, which can be solved separately. The main advantage of the operator splitting methods is that they provide a great flexibility in choosing different numerical methods, depending on the feature of each sub-problem. In this dissertation, we have developed highly accurate and efficient numerical methods for several nonlinear partial differential equations, which involve both linear and nonlinear operators. We first propose a fast explicit operator splitting method for the modified Buckley-Leverett equations which include a third-order mixed derivatives term resulting from the dynamic effects in the pressure difference between the two phases. The method splits the original equation into two equations, one with a nonlinear convective term and the other one with high-order linear terms so that appropriate numerical methods can be applied to each of the split equations: The high-order linear equation is numerically solved using a pseudo-spectral method, while the nonlinear convective equation is integrated using the Godunov-type central-upwind scheme. The spatial order of the central-upwind scheme depends on the order of the piecewise polynomial reconstruction: We test both the second-order minmod-based reconstruction and fifth-order WENO5 one to demonstrate that using higher-order spatial reconstruction leads to more accurate approximation of solutions. We then propose fast and stable explicit operator splitting methods for two phase-field models (the molecular beam epitaxy equation with slope selection and the Cahn-Hilliard equation), numerical simulations of which require long time computations. The equations are split into nonlinear and linear parts. The nonlinear part is solved using a method of lines combined with an efficient large stability domain explicit ODE solver. The linear part is solved by a pseudo-spectral method, which is based on the exact solution and thus has no stability restriction on the time step size. We have verified the numerical accuracy of the proposed methods and demonstrated their performance on extensive one- and two-dimensional numerical examples, where different solution profiles can be clearly observed and are consistent with previous analytical studies. / Zhuolin Qu

Development of Surface Acoustic Wave Sensors Using Nanostructured Palladium for Hydrogen Detection

Chaudhari, Amol V

08 July 2004

This thesis addresses the development of new gas sensor using surface acoustic wave (SAW) technology. SAW sensors detect the change in mass, modulus, and conductivity of a sensing layer material via absorption or adsorption of an analyte. The advantage of SAW sensor includes low cost, small size, high sensitivity. We investigated the use of nano-crystalline palladium film for sensing hydrogen gas. We also investigated SAW fabrication for radio frequency (RF) range operation where high signal-to-noise ratios can be achieved. A test-bed consisting of a gas dilution system, a temperature-controlled test cell, a network analyzer, and computer-based measurement system was used for evaluating the performance of SAW gas sensors at very low concentrations. Both single and dual delay line SAW devices were fabricated by means of photolithography on a lithium niobate substrate. Tests are carried to determine response speed, resolution, reproducibility, and linear characteristics, over a range of analyte concentrations.

network analyzer

e-beam lithography

American Studies

Arts and Humanities

Novel Pattern Reconfigurable Antenna Arrays Using Engineered Metamaterials and Microfluidic Principles

Gheethan, Ahmad

25 June 2014

This dissertation proposes novel solutions for important drawbacks of antenna arrays. One of the main contributions of the presented work is size reduction and nulling performance improvement of traditionally large anti-jam global positioning system (GPS) arrays using miniature antennas and electrically small resonators emulating an engineered metamaterial. Specifically, a miniaturized coupled double loop (CDL) dual band antenna is first introduced as a small antenna element of the compact GPS array. The loops that are capacitively coupled using lumped element capacitor, and employ metallic pins around their perimeter to improve the radiation efficiency by achieving a volumetric current distribution. This design is employed for the implementation of a compact 2x2 GPS array by reducing the inter-element spacing between the adjacent elements. However, having the antenna elements in close proximity of each other yields to a high mutual coupling and potentially degrades the nulling performance. The mutual coupling is performed by observing the magnetic field distribution within the array. It is noticed that the mutual coupling can be reduced by using metamaterial resonators. The right hand circular polarization (RHCP) radiation nature of the array complicates the mutual coupling suppression as compared to linear arrays. It is determined that split ring resonator (SRRs) are effective to mitigate the mutual coupling problem if placed strategically around the antenna elements. The study is verified experimentally where the mutual coupling is reduced by more than 10 dB. Lowering the mutual coupling improved the array's nulling capability by increasing the nulls depth by 8 dB as well as enhancing the accuracy of the nulls' locations. The second major contribution of the presented work is to introduce a novel microfluidic based beam-scanning technique for the implementation of low cost mm-wave antenna arrays. Traditionally, beam scanning capability is obtained using mechanical steering of the entire antenna structure or electronic components such as switches or phase shifters. The former is bulky, whereas the latter technique requires integrating substantial and expensive hardware in the array's feed network. For instance, a beam-scanning 1x8 focal plane array (FPA) would employ 7 single pole double through (SPDT) switches in its feed network. If an 8x8 FPA is desired, then 8x7+8 switches are required that results in an efficient design in terms of power loss and cost. In this dissertation, the microfluidic principles are introduced for designing and implementing affordable beam scanning antenna array with high gain radiation. Specifically, a microfluidic-based focal plane array 1x8 (MFPA) is designed and implemented at 30 GHz. The proposed MFPA consists of microfluidic channels connecting reservoirs. Both of the channels and reservoirs are filled with a low loss dielectric solution, and the antenna is formed by using a small volume of liquid metal. The beam scanning capability is obtained by placing the array at the focal point of a microwave lens and moving the antenna among the reservoirs using a micropump. Therefore, the feed network is extremely simplified by avoiding using SPDT switches. In addition, a strategic design methodology for a completely passive resonant based corporate feed network is discussed. The array is characterized numerically and verified experimentally. The simulated and measured performances are in a very good agreement with ±300 FoV and > 21 dB realized gain. However, the array's radiation pattern exhibits high side lobe level (SLL) due to the resonant nature of the introduced corporate feed network. Consequently, new resonant and non-resonant straight based feed networks are introduced to alleviate the high SLL issue. Moreover, they are modeled with appropriate equivalent circuits in order to analyze the array's performance analytically in terms of -10 dB |S11| bandwidth and power loss. The analytical solution is based on the transmission line theory and two ports network analysis. It is verified with the full wave simulations and a very good agreement is observed. Using the straight feed network reduces the SLL to more than 20 dB relative the pattern's peak. This enhancement in the performance is verified experimentally as well by designing, fabricating and testing a 30 GHz MFPA fed using a resonant based straight network. A ±250 FoV is obtained with a SLL < -20 dB and 4% -10 dB |S11| bandwidth.

Beam Scanning

Feed Networks

GPS

High Gain

MM-Wave

Engineering

The mandibular canal at the region of the molar teeth: an evaluation of cone beam volumetric tomography

Nguyen, Hai Ngoc

January 2008

Master of Science in Dentistry / Objectives: The aims of this study were: • to evaluate the exact level of the mandibular canal using Cone Beam Volumetric Tomography (CBVT) using measurements taken on images from the NewTom3G and i-CAT machines and manually • to determine the course of the mandibular canal in the regions of the first, second , and third molars • to compare the course of the mandibular canals bilaterally • to compare variables measured between the CBVT and panoramic units • to determine appropriate positions for the implant placement at the region of the mandibular molars in relation to the mandibular canal. Methods: Ten mandibles were selected, including seven edentulous and three dentate ones. They were marked at four positions from the distal border of the mental foramina in the posterior direction at intervals of 10.00 mm. On each dry mandible, at four sites namely M0, M1, M2, and M3, Gutta Percha (GP) points, known as markers, were attached to the mandible so that they were parallel to the midline of the mandible on both buccal and lingual sides. On the NewTom 3G and i-CAT, variables of cross-sectional images were measured from the alveolar crest of the mandible to the superior border of the mandibular canal (AC); the lingual rim of the canal to the lingual margin of the mandible (LC); the buccal rim of the canal to the buccal margin of the mandible (BC); the inferior rim of the canal to the lower border of the mandible (IC), and from the lingual margin to the buccal margin of the mandible (BW: Bone Width). Dry mandibles were subsequently sacrificed by cutting at the four marked sites. On each cross-section of mandibles, distances AC, BC, LC, IC, and BW were measured using a caliper as the manual measurement. IC distances on a conventional OrthophosIII panoramic machine were also measured to compare with the CBVT. Data were managed by Microsoft Office Excel 2003 and transferred to the software of Statistics Package for Social Sciences (SPSS) version 15.0 for Windows for analysis. Data were presented as Mean, Standard Deviation (SD), and Mean Difference, and Standard Error of Mean (SEM) with decimal at 0.00. T-test and One-way ANOVA were used to analyse variables measured in which T-test was used to analyse variables with paired samples and One-way ANOVA was used with adjustment for multiple comparisons of Bonferroni. Statistical significance has an assumed P- value of 0.05 or less. Results: The findings showed that there was no significant difference among measured variables from the NewTom 3G, i-CAT and manual measurement (P>0.05). There was significant statistical difference between the Orthophos OPG machine and CBVT system (P=0.00<0.05). There was no significant difference in the course of the mandibular canals bilaterally (P>0.05). On average, Distances AC, BC, LC, and IC were obtained for reference purposes. The bone width of the mandible on the right side was slightly different from that on the left side. Conclusions: The findings implied CBVT was an accurate diagnostic tool for locating the course of the mandibular canal and for placing dental implants in the region of the mandibular molars. The course of the mandibular canal on the left and right sides was variable. The distances measured at the region of the first, second, and third mandibular molars should be considered as a valuable reference. The bone width of the mandible on the right and left sides was slightly different. The accuracy of the NewTom3G and i-CAT was superior to the panoramic Orthophos machine. However, a panoramic radiograph is still valuable in the daily dental clinic.

Cone Beam Volumetric Tomography

Mandibular canal

Molar region

Monitoring and control of the CO2 laser cutting process

El-Kurdi, Zeyad, Mechanical & Manufacturing Engineering, Faculty of Engineering, UNSW

January 2005

Laser cutting is one of the most important applications of laser in manufacturing industry; it is mainly used for sheet metal cutting. In laser cutting, performing real-time evaluation of laser cut quality is very important to the advancement of this process in industry. However, due to the dynamic nature of the laser cutting process specially when cutting ferrous alloys using oxygen as an assist gas, laser cut quality cannot be easily predicted; therefore, the quality inspection of the laser cut is performed by off line inspections of the edges of the metal by skilled operators. This methodology is carried out after the process and thus cannot maintain a good quality if the process performance is out of control. Therefore, the objective of the research project is to qualify and develop a sensor system that ensure fault recognition online and can automatically control the laser metal cutting process to achieve good quality cut. For the realization of this objective the following has been done: - study the relationship between process parameters and cut quality characteristics; - identify the best sensors that can be used to monitor the process; - design and develop an experimental setup to test the proposed sensors; - collect and analyze data from the proposed sensors and correlate them to specific cut quality characteristics (process state variables); - develop direct relationships between the process signals and cut quality; - develop appropriate strategy for process control; - design and develop an integrated monitoring and control system; - test and evaluate the proposed system using simulation. In this study, a new technique for the determination of cut quality of sheet steels under the CO2 laser cutting process has been established. It is based on on-line detection and post-processing analysis of light radiation and acoustic emissions from the cut kerf. Determination of machining quality during cutting is best done through the measurement of surface roughness and kerf widths, as these are the two parameters that vary in successful through cuts. These two quality parameters can further be correlated to the two dominant process parameters of laser power and cutting speed. This study presents an analysis of acoustic emissions and reflected light for CO2 laser cutting of steel plates, and discusses their use for the estimation of cut quality parameters of kerf width and striation frequency for mild steel plates of 3mm, 5mm, 8mm, and 10mm thicknesses. Airborne acoustic and light signals are acquired with a microphone and a photodiode respectively, and recorded with a PC based data acquisition system in real time. The signals are then analyzed to establish a correlation between the signals obtained and the cut quality achieved. Experimental evidence shows that the energy levels of acoustic emission signals (RMS analysis) can be used to maintain the cutting process under steady state condition. On the other hand, the light intensity signal fluctuates with a frequency that corresponds to the frequency of striations formed on the cut surface; therefore it can be used to regulate cutting speed and laser power to obtain an optimum cutting condition and best cut quality. The validity of the proposed control strategy was tested experimentally by simulating the variations of cutting speed and examining their effect on the signals. So far, the prototype used for experimentation has been successful in providing correct information about cut quality in terms of striation frequency, and also about the state of the process where the microphone signal was successful in determining system failure or improper cutting conditions. A microprocessor based control system utilizing the PID control algorithm is recommended for the implementation of the control strategy. The implementation requirements of the proposed system for industrial use are then discussed. A new setup for the coaxial monitoring of CO2 laser cutting using a photodiode is proposed to enhance the quality of the signal and also to protect the photodiode from the harsh cutting environment. It is also proposed that an open control architecture platform is needed to enhance the integration of the proposed process control functions. Conclusions and future research directions towards the achievement of Autonomous Production Cell (APC) for the laser cutting process are then given.

Laser beam cutting

Metal-cutting

Carbon dioxide lasers

Industrial applications.