Global ETD Search

51	Study of the 3w Measurement of the In-Plane and the Cross-Plane Thermal Properties on Anisotropic Thin Film Materials Zhang, Daxi 01 December 2018 (has links) Due to the size of the nano-scale and micro-scale materials, traditional method for measuring the thermal properties of the bulk materials cannot be applied. The 3 OmegaMethod was developed by D. G. Cahill in the early 90s. It was used extensively to measure the thermal properties of thin film dielectric materials. Compare with other simulations or experimental methods, the 3 Omega Method has many advantages. Previous research has indicate that the 3 Omega method is capable of measuring the cross-plane thermal conductivity of thin film materials. In extension, an alternative improvement for measurement of the in-plane thermal conductivity and calculating the difference between the in-plane thermal property and the cross-plane thermal property (anisotropy) are developed based on the concept of the 3 Omega Method. 3 Omega Measurement Thin Film Material Anisotropic Mechanical Engineering
52	Simulation of cubic GaN growth in SA MOVPE Nilsson, Daniel January 2009 (has links) <p><p>In this work growth of cubic GaN in the selective area (SA) MOVPE process is</p><p>simulated. The simulations are restricted to small pattern SA MOVPE growth.</p><p>In this case the traditional MOVPE growth and the enhanced growth caused by</p><p>surface diffusion are important growth factors. The lateral vapor phase diffusion</p><p>is ignored while this process only has a small impact on the enhanced growth in</p><p>the small pattern SA growth. The model is build for simulation of anisotropic</p><p>growth. It has been shown that different type of anisotropic growth occurs when</p><p>the mask pattern are orientated in different directions on the substrate. While</p><p>the anisotropic growth is not well understood two different models are studied in</p><p>this work.</p><p>The simulation is restricted to the geometrical growth characteristics such</p><p>as mask and crystal width, mask alignment and surface diffusion on the crystal.</p><p>The reactor geometry, pressure and growth temperature are not investigated that</p><p>closely and are only treated as constants in the model.</p><p>The model used in this simulation gives good results for short time simulations</p><p>for some certain cases. The model shows that the fill factor has a greater</p><p>impact on the grown shapes than the individual mask and crystal width. But</p><p>there are problems with the anisotropic and flux from mask modeling while some</p><p>facets do not appear and the lateral growth along the mask show doubtful results.</p><p>The model show good results in short time growth and predict some important</p><p>characteristics in SA MOVPE.</p></p> simulation gallium nitride SAG MOVPE anisotropic Physics Fysik
53	The Effect of Bonner Sphere Borehole Orientation on Neutron Detector Response Brittingham, John Macdougall 01 December 2010 (has links) This thesis investigates the differences in Bonner Sphere detector response for anisotropic neutron fields as a function of borehole orientation. Monte Carlo simulations using MCNPX were used to calculate the difference for a borehole oriented directly behind a unidirectional neutron field and one in which the borehole is normal to the neutron flux. The differences in detector response depend on the size of the Bonner Sphere and the energy of the incident flux, which could introduce significant error in the determination of the neutron field’s energy spectrum. Bonner Sphere borehole anisotropic response function Nuclear Engineering
54	Toeplitz operators and division theorems in anisotropic spaces of holomorphic functions in the polydisc Harutyunyan, Anahit V. January 2001 (has links) This work is an introduction to anisotropic spaces, which have an ω-weight of analytic functions and are generalizations of Lipshitz classes in the polydisc. We prove that these classes form an algebra and are invariant with respect to monomial multiplication. These operators are bounded in these (Lipshitz and Djrbashian) spaces. As an application, we show a theorem about the division by good-inner functions in the mentioned classes is proved. Toeplitz operators anisotropic spaces polydisc good-inner function Mathematics
55	Hydro-mechanical forming of aluminium tubes : on constitutive modelling and process design Jansson, Mikael January 2006 (has links) Tube hydroforming is a forming method which has several advantages. By using pressure in combination with material feeding it is possible to manufacture products with high structural integration and tight dimensional tolerances. The forming method is especially suited for aluminium alloys which have a relatively low ductility. Finite Element simulations are used extensively in the sheet metal stamping industry, where the methodology has contributed to a better understanding of the process and the new prediction capability has significantly reduced costly die tryouts. Similarly, the tube hydroforming industry can benefit from Finite Element simulations, and this simulation methodology is the topic of this dissertation. Deep drawing and tube hydroforming have a basic difference, namely that the latter process essentially is a force controlled process. This fact, in combination with the anisotropic behaviour of aluminium tubes, enforces a need for accurate constitutive descriptions. Furthermore, the material testing needs to account for the specifics of tube hydroforming. The importance of proper material modelling is in this work shown for hydrobulging and hydroforming in a die with extensive feeding. The process parameters in hydroforming are the inner pressure and the material feeding, where a correct combination of these parameters is crucial for the success of the process. It is here shown, that Finite Element simulations together with an optimisation routine are powerful tools for estimating the process parameters in an automated procedure. Finally, the reliability and quality of the simulation results depend on how failure is evaluated, which in the case of hydroforming mainly oncerns wrinkling and strain localisation. Since tube hydroforming often is preceded by bending operations this fact also demands the criteria to be strain path independent. In this work, it is shown that the prediction of strain localisation depends on the ability to predict diffuse necking, which in turn is strongly related to the chosen constitutive model. Hydroforming Aluminium Extrusions Anisotropic material Solid mechanics Fastkroppsmekanik
56	Simulation of cubic GaN growth in SA MOVPE Nilsson, Daniel January 2009 (has links) In this work growth of cubic GaN in the selective area (SA) MOVPE process is simulated. The simulations are restricted to small pattern SA MOVPE growth. In this case the traditional MOVPE growth and the enhanced growth caused by surface diffusion are important growth factors. The lateral vapor phase diffusion is ignored while this process only has a small impact on the enhanced growth in the small pattern SA growth. The model is build for simulation of anisotropic growth. It has been shown that different type of anisotropic growth occurs when the mask pattern are orientated in different directions on the substrate. While the anisotropic growth is not well understood two different models are studied in this work. The simulation is restricted to the geometrical growth characteristics such as mask and crystal width, mask alignment and surface diffusion on the crystal. The reactor geometry, pressure and growth temperature are not investigated that closely and are only treated as constants in the model. The model used in this simulation gives good results for short time simulations for some certain cases. The model shows that the fill factor has a greater impact on the grown shapes than the individual mask and crystal width. But there are problems with the anisotropic and flux from mask modeling while some facets do not appear and the lateral growth along the mask show doubtful results. The model show good results in short time growth and predict some important characteristics in SA MOVPE. simulation gallium nitride SAG MOVPE anisotropic Physics Fysik
57	A Study of Interface Crack Branching in Dissimilar Anisotropic Bimaterial Composites Including Thermal Li, Renfu 30 November 2004 (has links) The interface crack branching phenomena, including thermal effects, has been investigated by using complex variable method and Stroh's dislocation theory, extended to thermo-elasticity in matrix notation. As one of the most catastrophic failure modes in structures like laminated and sandwich composites in aerospace and marine construction, thin film in electronic packaging, rotators in high speed engine of aircraft and reactor in nuclear power station, the study of interface crack branching has become a topic not only having theoretical importance, but also having practical significance. A unified approach is presented to address the thermoelastic interface crack problems in dissimilar anisotropic bimaterial composites, and a compact closed form solution is formulated by analytical continuation principle of complex analysis. Employing the contour integral method, an explicit solution to the interaction between the dislocations and the interface crack is obtained. By modeling the branched portion as a continuous distribution of the dislocations, the thermoelastic interface crack branching problem is then converted to a set of semi-coupled singular integral equations and solved by Gauss-Jacobi integration schemes. The influence of material property mismatches between the two constituents and the thermal loading effects on the interface crack branching are demonstrated by extensive numerical simulation. Some useful criteria for predicting the interface crack branching growth and guidance for optimal composites design are suggested. Further, a contact model to eliminate the overlapping between the two surfaces of an interface crack is also proposed and some new parameters which could influence the interpenetrating phenomena are also discovered. The technique to extend the current method to three dimensional problems is also outlined. Furthermore, the C++ source code has been implemented to manipulate the complicated complex operations for numerically solving the singular integral equations in complex matrix form. Interface crack Branching Dissimilar Anisotropic Bimaterial composites Thermal effects
58	A study of the transformation bandwidth and the thickness sensitivity of the anisotropic-slab LP to CP polarizer Huang, Yung-Ching 04 October 2003 (has links) In this thesis, we investigate the transformation bandwidth and the thickness sensitivity of the anisotropic-slab linearly polarizes (LP) to circularly polarized (CP) polarizer. We define a transformation bandwidth and the thickness sensitivity based on the axial ratio. New methods are proposed that can eliminate the lengthy derivation and give deeper physical insight to the problem. Under the small reflection approximation, i.e., only the forward waves are considered, our methods can be applied to the design of the anisotropic-slab LP to CP polarizer. For the single anisotropic slab, the effect is represented graphically on the polarization ratio plane. It is shown that the polarization locus for a given axial ratio leads to a circle in the polarization state diagram. When combined with the graphical description of the change in the polarization state, the transformation bandwidth and the thickness sensitivity from an initial LP wave to a desired CP wave can be obtained easily. Furthermore, we present a method using the equivalent circuits to represent the polarization effect in anisotropic media, so that some concepts of the electric circuit can be applied. This method is more convenient in dealing with the polarization change when multiple anisotropic-slabs exist. The transformation bandwidths and the thickness sensitivities for the anisotropic-slab polarizer for several lossless media are studied. The results are discussed and illustrated. Anisotropic Media Polarization Transformation LP to CP Polarizer
59	A Study of Flexural Plate Wave Device with High C-axis Orientation ZnO Piezoelectric Film and Interdigital Transducer Chang, Yi-Wen 13 July 2006 (has links) By integrating Nanotechnology and MEMS technology, this thesis aims to research a flexural-plate wave (FPW) sensor for testing Immunoglobulin E (IgE) concentration in blood serum, a significant index for the diagnosis of allergies. The traditional methods of blood assay are time-consuming and costly, and its average accuracy of only 60-70 percent. After compare the major four kinds of acoustic sensor, the FPW sensor demonstrates a high accuracy, high sensitivity, low operation frequency, low diagnosis time and low cost. This thesis utilizes a reactive RF sputter system to deposite the piezoelectric ZnO thin film. To obtain the high C-axis orientation (002) characteristic of ZnO membrane, many parameters such as substrate temperature, Ar/O2 ratio and RF power have been adjusted and optimized during the sputtering process. The effects of varied parameters will be investigated and analysis by using SEM or XRD facilities. In this study, we combined the high figure-of-merits ZnO deposition techniques and single-side anisotropic silicon etch process to implement the process integration of FPW device. Finally, this research has demonstrated a 50-60MHz center frequency can be extracted from such silicon-based FPW microsensor. ZnO piezoelectric film reactive RF sputter anisotropic etching FPW
60	Analytical Solution of the Continuous Cellular Automaton for Anisotropic Etching Gosálvez, Miguel A., Xing, Yan, Sato, Kazuo, 佐藤, 一雄 04 1900 (has links) No description available. Anisotropic etching cellular automata (CA) simulation step flow surface processing

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