Effective properties of three-phase electro-magneto-elastic multifunctional composite materials

Lee, Jae Sang

17 February 2005

Coupling between the electric field, magnetic field, and strain of composite materials is achieved when electro-elastic (piezoelectric) and magneto-elastic (piezomagnetic) particles are joined by an elastic matrix. Although the matrix is neither piezoelectric nor piezomagnetic, the strain field in the matrix couples the E field of the piezoelectric phase to the B field of the piezomagnetic phase. This three-phase electro-magneto-elastic composite should have greater ductility and formability than a two-phase composite in which E and B are coupled by directly bonding two ceramic materials with no compliant matrix. A finite element analysis and homogenization of a representative volume element is performed to determine the effective electric, magnetic, mechanical, and coupled-field properties of an elastic (epoxy) matrix reinforced with piezoelectric and piezomagnetic fibers as functions of the phase volume fractions, the fiber (or particle) shapes, the fiber arrangements in the unit cell, and the fiber material properties with special emphasis on the symmetry properties of the fibers and the poling directions of the piezoelectric and piezomagnetic fibers. The effective magnetoelectric moduli of this three-phase composite are, however, less than the effective magnetoelectric coefficients of a two-phase piezoelectric/piezomagnetic composite, because the epoxy matrix is not stiff enough to transfer significant strains between the piezomagnetic and piezoelectric fibers.

magnetoelectric

piezomagnetic

piezoelectric

multifunctional material

effective property

three phase

Effective properties of three-phase electro-magneto-elastic multifunctional composite materials

Lee, Jae Sang

17 February 2005

Coupling between the electric field, magnetic field, and strain of composite materials is achieved when electro-elastic (piezoelectric) and magneto-elastic (piezomagnetic) particles are joined by an elastic matrix. Although the matrix is neither piezoelectric nor piezomagnetic, the strain field in the matrix couples the E field of the piezoelectric phase to the B field of the piezomagnetic phase. This three-phase electro-magneto-elastic composite should have greater ductility and formability than a two-phase composite in which E and B are coupled by directly bonding two ceramic materials with no compliant matrix. A finite element analysis and homogenization of a representative volume element is performed to determine the effective electric, magnetic, mechanical, and coupled-field properties of an elastic (epoxy) matrix reinforced with piezoelectric and piezomagnetic fibers as functions of the phase volume fractions, the fiber (or particle) shapes, the fiber arrangements in the unit cell, and the fiber material properties with special emphasis on the symmetry properties of the fibers and the poling directions of the piezoelectric and piezomagnetic fibers. The effective magnetoelectric moduli of this three-phase composite are, however, less than the effective magnetoelectric coefficients of a two-phase piezoelectric/piezomagnetic composite, because the epoxy matrix is not stiff enough to transfer significant strains between the piezomagnetic and piezoelectric fibers.

magnetoelectric

piezomagnetic

piezoelectric

multifunctional material

effective property

three phase

Transport Phenomena in Cathode Catalyst Layer of PEM Fuel Cells

Das, Prodip

January 2010

Polymer electrolyte membrane (PEM) fuel cells have increasingly become promising green energy sources for automobile and stationary cogeneration applications but its success in commercialization depends on performance optimization and manufacturing cost. The activation losses, expensive platinum catalyst, and water flooding phenomenon are the key factors currently hindering commercialization of PEM fuel cells. These factors are associated with the cathode catalyst layer (CCL), which is about ten micrometers thick. Given the small scale of this layer, it is extremely difficult to study transport phenomena inside the catalyst layer experimentally, either intrusively or non-intrusively. Therefore, mathematical and numerical models become the only means to provide insight on the physical phenomena occurring inside the CCL and to optimize the CCL designs before building a prototype for engineering application. In this thesis research, a comprehensive two-phase mathematical model for the CCL has been derived from the fundamental conservation equations using a volume-averaging method. The model also considers several water transport and physical processes that are involved in the CCL. The processes are: (a) electro-osmotic transport from the membrane to the CCL, (b) back-diffusion of water from the CCL to the membrane, (c) condensation and evaporation of water, and (d) removal of liquid water to the gas flow channel through the gas diffusion layer (GDL). A simple analytical model for the activation overpotential in the CCL has also been developed and an optimization study has been carried out using the analytical activation overpotential formulation. Further, the mathematical model has been simplified for the CCL and an analytical approach has been provided for the liquid water transport in the catalyst layer. The volume-averaged mathematical model of the CCL is finally implemented numerically along with an investigation how the physical structure of a catalyst layer affects fuel cell performance. Since the numerical model requires various effective transport properties, a set of mathematical expressions has been developed for estimating the effective transport properties in the CCL and GDL of a PEM fuel cell. The two-dimensional (2D) numerical model has been compared with the analytical model to validate the numerical results. Subsequently, using this validated model, 2D numerical studies have been carried out to investigate the effect of various physical and wetting properties of CCL and GDL on the performance of a PEM fuel cell. It has been observed that the wetting properties of a CCL control the flooding behavior, and hydrophilic characteristics of the CCL play a significant role on the cell performance. To investigate the effect of concentration variation in the flow channel, a three-dimensional numerical simulation is also presented.

Activation Overpotential

Effective Property

Mathematical Modeling

Numerical Simulation

PEM fuel Cell

Transport phenomena

Mechanical Engineering

Transport Phenomena in Cathode Catalyst Layer of PEM Fuel Cells

Das, Prodip

January 2010

Polymer electrolyte membrane (PEM) fuel cells have increasingly become promising green energy sources for automobile and stationary cogeneration applications but its success in commercialization depends on performance optimization and manufacturing cost. The activation losses, expensive platinum catalyst, and water flooding phenomenon are the key factors currently hindering commercialization of PEM fuel cells. These factors are associated with the cathode catalyst layer (CCL), which is about ten micrometers thick. Given the small scale of this layer, it is extremely difficult to study transport phenomena inside the catalyst layer experimentally, either intrusively or non-intrusively. Therefore, mathematical and numerical models become the only means to provide insight on the physical phenomena occurring inside the CCL and to optimize the CCL designs before building a prototype for engineering application. In this thesis research, a comprehensive two-phase mathematical model for the CCL has been derived from the fundamental conservation equations using a volume-averaging method. The model also considers several water transport and physical processes that are involved in the CCL. The processes are: (a) electro-osmotic transport from the membrane to the CCL, (b) back-diffusion of water from the CCL to the membrane, (c) condensation and evaporation of water, and (d) removal of liquid water to the gas flow channel through the gas diffusion layer (GDL). A simple analytical model for the activation overpotential in the CCL has also been developed and an optimization study has been carried out using the analytical activation overpotential formulation. Further, the mathematical model has been simplified for the CCL and an analytical approach has been provided for the liquid water transport in the catalyst layer. The volume-averaged mathematical model of the CCL is finally implemented numerically along with an investigation how the physical structure of a catalyst layer affects fuel cell performance. Since the numerical model requires various effective transport properties, a set of mathematical expressions has been developed for estimating the effective transport properties in the CCL and GDL of a PEM fuel cell. The two-dimensional (2D) numerical model has been compared with the analytical model to validate the numerical results. Subsequently, using this validated model, 2D numerical studies have been carried out to investigate the effect of various physical and wetting properties of CCL and GDL on the performance of a PEM fuel cell. It has been observed that the wetting properties of a CCL control the flooding behavior, and hydrophilic characteristics of the CCL play a significant role on the cell performance. To investigate the effect of concentration variation in the flow channel, a three-dimensional numerical simulation is also presented.

Activation Overpotential

Effective Property

Mathematical Modeling

Numerical Simulation

PEM fuel Cell

Transport phenomena

Mechanical Engineering

Materials selection and evaluation of Cu-W particulate composites for extreme electrical contacts

Watkins, Bobby Gene, II

21 January 2011

Materials for extreme electrical contacts need to have high electrical conductivity coupled with good structural properties. Potential applications include motor contacts, high power switches, and the components of electromagnetic launch (EML) systems. In particular, the lack of durability of these materials in rail components limits practical EML implementation. These rails experience significant amounts of Joule heating, due to extreme current densities, and subsequent thermally-assisted wear. New more durable materials solutions are needed for these components. A systematic materials selection study was executed to identify and compare candidate materials solutions. Several possible candidate non-dominated materials as well as hybrid materials that could potential fill the "white spaces" on the Ashby charts were identified. A couple potential candidate materials were obtained and evaluated. These included copper-tungsten W-Cu, "self-lubricating" graphite-impregnated Cu, and Gr-W-Cu composites with different volume fractions of the constituents. The structure-property relations were determined through mechanical and electrical resistivity testing. A unique test protocol for exposing mechanical test specimens to extreme current densities up to 1.2 GA/m2 was developed and used to evaluate these candidate materials. The systematic design of multi-functional materials for these extreme electrical contacts requires more than an empirical approach. Without a good understanding of both the tribological and structural performance, the optimization of the microstructure will not be quickly realized. By using micromechanics modeling and other materials design modeling tools coupled with systematic mechanical and tribological experiments, the design of materials for these applications can potentially be accelerated. In addition, using these tools, more complex functionally-graded materials tailored to the application can be systematically designed. In this study, physics- and micromechanics-based models were used to correlate properties to the volume fraction of the constituents of the evaluated candidate materials. Properties correlated included density, elastic modulus, hardness, strength, and electrical resistivity of the W-Cu materials.

Electrical conductivity

Hybrid materials design

Tensile property evaluation

Ashby method

Railgun

Effective property modeling

Electric conductivity

Electric conductors

Materials

Materials Analysis

Materials Research

財產稅相關議題之研究-以台北市自用住宅為例 / Essays on Property Tax

陳揚仁, Chen, Yang Jen

Unknown Date

財產稅分成單一稅率財產稅制以及雙率財產稅制。財產稅稅基依賴的是評估價值，稅基通常沒有正確反應市價，雙率的財產稅制在有效稅率以及評估比率估算上皆較單一稅率稅制複雜；此外，房價居高不下之下，財產稅資本化效果的探討更有其必要性，因此本研究選取財產稅制度已實施雙率稅制數十年台灣的首都台北市，並且選取自用住宅為樣本，探討在雙率稅制下，衡量「1－評估比率」、財產稅有效稅率、以及探討財產稅資本化效果。 有效稅率以及評估比率方面，結論可以得知台北市及12個行政區之「自用住宅」財產稅有效稅率皆有極為偏低的現象，以及台北市以及每一個行政區的平均「1-評估比率」都至少有七成以上，這表示政府相關單位必須要將評估比率提高，提高財產稅有效稅率，才能有效降低稅基與市場價格之間的偏離程度。此外，土地與房屋分離課稅，地價稅的稅基土地公告地價以及房屋稅稅基房屋評定現值由不同評價委員會估價之下，容易產生評估比率偏低狀況，因此建議將不動產評議委員會以及地價評議委員會合併成單一的委員會，在評估價值的誤差應該會有顯著的降低。 財產稅資本化效果方面，發現台北市自用住宅的財產稅稅賦負擔太輕，尤其是地價稅，因此無法透過提高財產稅的方式來抑制房價。此外，根據分量迴歸的結果發現，房屋稅支出愈高，低房價的房屋總價會降低，這結果表示在低房價房屋稅的租稅負擔是高於最適水準；然而高房價的房屋總價會因房屋稅支出愈高反而愈高，這結果表示在高房價房屋稅的租稅負擔是低於最適水準。因此透過這些發現，建議台北市政府相關單位應將高房價的房屋稅租稅負擔提高超過最適水準，藉由此才能有效的抑制房價的上漲。 / This paper investigates the assessment ratio, effective property tax rate and property tax capitalization for owner-occupied residential houses in Taipei, which employs a split-rate property tax system. The analysis finds that the effective property tax burden is lower in Taipei. Therefore, the tax authority should work to raise the effective property tax rates and minimize the biases in order to raise assessment ratios. Ideally, if the committees could be integrated into a single committee, assessed value biases may be able to be significantly reduced. In property tax capitalization, we find that current property tax rate is smaller than the optimal one in Taipei. Current property tax burden especially from the land value tax is too light, so a higher property tax rate cannot be negatively capitalized into the house prices. Moreover, we also find that there is a positive house tax capitalization only for the high value houses, but a negative house tax capitalization for low value houses. These findings imply that Taipei authority has to raise the property tax burden especially for high value houses to be above the optimal level if it wants to effectively cool down the rising house value.

雙率財產稅稅制

財產稅有效稅率

評估稅率

財產稅資本化效果

Split-rate Property Tax

Effective Property Tax Rate

Assessment Ratio

Property Tax Capitalization