Bead Modeling of Transport Properties of Macromolecules in Free Solution and in a Gel

Pei, Hongxia

15 June 2010

On the bead modeling methodology, or BMM, a macromolecule is modeled as a rigid, non-overlapping bead array with arbitrary radii. The BMM approach was pioneered by Kirkwood and coworkers (Kirkwood, J.G., Macromolecules, E.P. Auer (Ed.), Gordon and Breach, New York, 1967; Kirkwood, J.G., Riseman, J., J. Chem. Phys., 1948, 16, 565) and applied to such transport properties as diffusion, sedimentation, and viscosity. With the availability of computers, a number of investigators extended the work to account for the detailed shape of biomolecules in the 1970s. A principle objective of my research has been to apply the BMM approach to more complex transport phenomena such as transport in a gel, electrophoresis (free solution and in a gel), and also transport in more complex media (such as the viscosity of alkanes and benzene). Variables considered by the BMM include the number of beads (N), the radii of the beads, net charge and charge distribution, conformations, salt type, and salt concentration. The BMM has been extended to: (1) account for the existence of a gel; (2) characterize the charge and secondary structure of macromolecules; (3) account more accurately for hydrodynamic interaction (remove the orientationnal preaveraging approximation of hydrodynamic interaction); (4) study the effect of ion relaxation for particles in arbitrary size, shape, and charge; (5) consider the salt dependence of electrokinetic properties; (6) account for the formation of possible complex between guest ions and BGE ions. We also did diffusion constant measurement by NMR for amino acids and short peptides in 10%D2O-90% H2O at room temperature and applied to our modeling study by BMM.

Agarose gel

Bead model

Complex formation

DNA

Effective medium

Hydrodynamic interaction

NMR

Peptide

Relaxation

Salt dependence

Chemistry

Optical Modeling of Amorphous and Metal Induced Crystallized Silicon with an Effective Medium Approximation

Muller, Theophillus Frederic George

January 2009

<p>Hydrogenated amorphous silicon (a-Si:H) is second only to crystalline silicon in volume manufacturing of solar cells due to its attractive characteristics for solar panel manufacturing. These are lower manufacturing costs, and the fact that it can be deposited on any surface, and in any shape even on flexible substrates. The metal induced crystallization of hydrogenated amorphous silicon has been the subject of intense scrutiny in recent years. By combining the technology of hydrogenated amorphous silicon thin films with the superior characteristics of c-Si material, it is hoped that more efficient solar cells can be produced. In this thesis we report on the metal-mediated-thermally induced changes of the structural and optical properties of hydrogenated amorphous silicon deposited by hot-wire CVD, where aluminium and nickel were used to induce crystallization. The metal-coated amorphous silicon was subjected to a thermal annealing regime of between 150 and 520&deg / C. The structural measurements, obtained by Raman spectroscopy, show partial crystallization occurring at 350 &deg / C. At the higher annealing temperatures of 450&deg / C and 520&deg / C complete crystallization occurs. Reflection and transmission measurements in the UV-visible range were then used to extract the optical properties. By adopting the effective medium approximation a single optical model could be constructed that couldsuccessfully model material that was in different structural phases, irrespective of metal contamination. Changes in the absorption of the material in various stages of transition were confirmed with a directly measured absorption technique, and the modelled absorption closely followed the same trends This study forms part of the larger overall solar cell research project, of which the primary aim is to eventually develop a silicon solar panel that optimises the characteristics for best performance.</p>

Metal induced crystallization

Polycrystalline silicon

Annealing

Effective medium approximation

Optical modeling

Absorption

Band gap

Phase Transition

Protocrystalline silicon

Structural order.

Study of the radiative properties of aligned carbon nanotubes and silver nanorods

Wang, Xiaojia

11 November 2011

Arrays of nanotubes/rods made of appropriate materials can yield unique radiative properties, such as large absorption and optical anisotropy, with broad applications from high-efficiency emitters and absorbers for energy conversion to the polarization conversion via anisotropic responses. The objective of this dissertation is to investigate the radiative properties of arrays formed by aligned carbon nanotubes (CNTs) and silver nanorods (AgNRs). The CNT arrays used in the present study consist of multi-walled CNTs synthesized vertically on silicon substrates using thermal chemical vapor deposition. Their close-to-unity absorptance is demonstrated by measuring the directional-hemispherical reflectance in the visible and near-infrared spectral ranges using an integrating sphere. The bidirectional reflectance distribution function and angle-resolved reflectance were measured at the 635-nm wavelength. The results demonstrate that high-absorptance CNT arrays may be diffusely or specularly reflecting and have important applications in radiometry. Theoretical modeling based on the effective medium theory (EMT) and reflectivity of an anisotropic medium are developed to explain the high absorption and polarization dependence. The effective optical constants of the CNT array for both ordinary and extraordinary polarizations are quantitatively determined by fitting the angle-resolved reflectance. The AgNR arrays used in the present study were fabricated using oblique angle deposition, which results in inclined Ag nanorods that can be modeled as an effective homogenous and optically anisotropic thin film. The spectral and directional radiative properties of AgNRs grown on different substrates, including a glass slab with a silver film, and compact disc gratings, were characterized at the 635-nm and 977-nm wavelengths for different polarizations. The results are analyzed based on the EMT, rigorous coupled-wave analysis, and anisotropic thin-film optics. The results of this dissertation help gain a better understanding of radiative properties of anisotropic nanostructures for potential applications in high-efficiency energy conversion, radiometric devices, and optical systems.

Thermal radiation

Nanoarray

Effective medium

Anisotropic wave propagation

BRDF

Scattering

Nanotubes

Nanostructured materials

Carbon

Radiative transfer

Silver

Optical Modeling of Amorphous and Metal Induced Crystallized Silicon with an Effective Medium Approximation

Muller, Theophillus Frederic George

January 2009

<p>Hydrogenated amorphous silicon (a-Si:H) is second only to crystalline silicon in volume manufacturing of solar cells due to its attractive characteristics for solar panel manufacturing. These are lower manufacturing costs, and the fact that it can be deposited on any surface, and in any shape even on flexible substrates. The metal induced crystallization of hydrogenated amorphous silicon has been the subject of intense scrutiny in recent years. By combining the technology of hydrogenated amorphous silicon thin films with the superior characteristics of c-Si material, it is hoped that more efficient solar cells can be produced. In this thesis we report on the metal-mediated-thermally induced changes of the structural and optical properties of hydrogenated amorphous silicon deposited by hot-wire CVD, where aluminium and nickel were used to induce crystallization. The metal-coated amorphous silicon was subjected to a thermal annealing regime of between 150 and 520&deg / C. The structural measurements, obtained by Raman spectroscopy, show partial crystallization occurring at 350 &deg / C. At the higher annealing temperatures of 450&deg / C and 520&deg / C complete crystallization occurs. Reflection and transmission measurements in the UV-visible range were then used to extract the optical properties. By adopting the effective medium approximation a single optical model could be constructed that couldsuccessfully model material that was in different structural phases, irrespective of metal contamination. Changes in the absorption of the material in various stages of transition were confirmed with a directly measured absorption technique, and the modelled absorption closely followed the same trends This study forms part of the larger overall solar cell research project, of which the primary aim is to eventually develop a silicon solar panel that optimises the characteristics for best performance.</p>

Metal induced crystallization

Polycrystalline silicon

Annealing

Effective medium approximation

Optical modeling

Absorption

Band gap

Phase Transition

Protocrystalline silicon

Structural order.

Optical modeling of amorphous and metal induced crystallized silicon with an effective medium approximation

Theophillus Frederic George Muller

January 2009

<p>In this thesis we report on the metal-mediated-thermally induced changes of the structural and optical properties of hydrogenated amorphous silicon deposited by hot-wire CVD, where aluminium and nickel were used to induce crystallization. The metal-coated amorphous silicon was subjected to a thermal annealing regime of between 150 and 520&deg / C. The structural measurements, obtained by Raman spectroscopy, show partial crystallization occurring at 350 &deg / C. At the higher annealing temperatures of 450&deg / C and 520&deg / C complete crystallization occurs. Reflection and transmission measurements in the UV-visible range were then used to extract the optical properties. By adopting the effective medium approximation a single optical model could be constructed that could successfully model material that was in different structural phases, irrespective of metal contamination. Changes in the absorption of the material in various stages of transition were confirmed with a directly measured absorption technique, and the modelled absorption closely followed the same trends This study forms part of the larger overall solar cell research project, of which the primary aim is to eventually develop a silicon solar panel that optimises the characteristics for best performance.</p>

Metal induced crystallization

Polycrystalline silicon

Annealing

Effective medium approximation

Optical modeling

Absorption

Band gap

Phase Transition

Protocrystalline silicon

Structural order

A Study of gas hydrates with ocean-bottom-seismometer data on the East Coast of Canada

Schlesinger, Angela

24 January 2013

This dissertation presents a study on velocity modeling using ocean-bottom seismometer data (OBS) collected in 2004 and 2006 on the western Scotian slope. Gas hydrate and free gas concentrations and their distribution along the Scotian margin were derived based on the velocity results modeled with two different OBS data sets. A strong velocity increase (140-300 m/s) associated with gas hydrate was modeled for a depth of 220 m below seafloor (bsf). At the base of that high velocity zone (330 mbsf) the velocity decreases with 50-130 m/s. This depth is associated with the depth of the bottom-simulating reflector (BSR) observed in previous 2-D seismic reflection data. The gas hydrate concentrations (2-18 %) based on these velocities were calculated with an effective medium model. The velocity modeling shows that a sparser OBS spacing (~ 1 km) reveals more velocity uncertainties and smaller velocity contrasts than a denser (100 m) spaced OBS array. The results of the travel-time inverse modeling are applied in a waveform inverse modeling with OBS data in the second part of the thesis. The modeling tests were performed to obtain information on OBS instrument spacings necessary to detect low-concentration gas hydrate occurrences. The model runs show that an increase in instrument spacing leads to an increasing loss of model smoothness. However, large instrument spacings (>500 m) are beneficial for covering a wide target region with only using a few instruments, but decreasing the lateral resolution limits of the subsurface targets. In general half of the instrument spacing defines the lower boundary for the lateral width of the target structure. Waveform modeling with the 2006 OBS data has shown that low frequencies (<8 Hz) in the source spectrum are necessary to recover the background velocity of the model. The starting model derived from travel-time inversion of the 2006 data is not close enough to the true model. Thus the first-arrival waveforms do not match within half a cycle. Modeling with a starting frequency of 8 Hz and and applying data with a low signal-to-noise ratio (1.25) introduces artifacts into the final model result without updating the velocity. / Graduate

gas hydrate

Ocean-Bottom Seismometer

Nova Scotia margin

travel-time inversion

frequency domain waveform inversion

effective medium modeling

Optical modeling of amorphous and metal induced crystallized silicon with an effective medium approximation

Muller, Theophillus Frederic George

January 2009

Philosophiae Doctor - PhD / In this thesis we report on the metal-mediated-thermally induced changes of the structural and optical properties of hydrogenated amorphous silicon deposited by hot-wire CVD, where aluminium and nickel were used to induce crystallization. The metal-coated amorphous silicon was subjected to a thermal annealing regime of between 150 and 520°C. The structural measurements, obtained by Raman spectroscopy, show partial crystallization occurring at 350 °C. At the higher annealing temperatures of 450°C and 520°C complete crystallization occurs. Reflection and transmission measurements in the UV-visible range were then used to extract the optical properties. By adopting the effective medium approximation a single optical model could be constructed that could successfully model material that was in different structural phases, irrespective of metal contamination. Changes in the absorption of the material in various stages of transition were confirmed with a directly measured absorption technique, and the modelled absorption closely followed the same trends This study forms part of the larger overall solar cell research project, of which the primary aim is to eventually develop a silicon solar panel that optimises the characteristics for best performance. / South Africa

Metal induced crystallization

Polycrystalline silicon

Annealing

Effective medium approximation

Optical modeling

Absorption

Band gap

Phase Transition

Protocrystalline silicon

Structural order

Advanced characterisation and optical simulation for the design of solar selective coatings based on carbon:transition metal carbide nanocomposites

Heras, I., Krause, M., Abrasonis, G., Pardo, A., Endrino, J. L., Guillén, E., Escobar-Galindo, R.

07 May 2019

Solar selective coatings based on carbon transition metal carbide nanocomposite absorber layers were designed. Pulsed filtered cathodic arc was used for depositing amorphous carbon: metal carbide (a-C:MeC, Me = V, Mo) thin films. Composition and structure of the samples were characterized by ion beam analysis, X-ray diffraction, Raman spectroscopy, and transmission electron microscopy. The optical properties were determined by ellipsometry and spectrophotometry. Three effective medium approximations (EMA), namely Maxwell-Garnett, Bruggeman, and Bergman, were applied to simulate the optical behaviour of the nanocomposite thin films. Excellent agreement was achieved between simulated and measured reflectance spectra in the entire wavelength range by using the Bergman approach, where in-depth knowledge of the nanocomposite thin film microstructure is included. The reflectance is shown to be a function of the metal carbide volume fraction and its degree of percolation, but not dependent on whether the nanocomposite microstructure is homogeneous or a self-organized multilayer. Solar selective coatings based on an optimized a-C:MeC absorber layer were designed exhibiting a maximum solar absorptance of 96% and a low thermal emittance of ~5 and 15% at 25 and 600ºC, respectively. The results of this study can be considered as predictive design tool for nanomaterial-based optical coatings in general.

Directional Emission of Light in Hyperbolic Metamaterials and Its Application in Miniature Polarimeter

Chen, Hongwei

26 September 2019

No description available.

Optics

Electrical Engineering

Photonic spin Hall effect

metamaterials

hyperbolic metamaterials

polarization

polarimeters

directional emission

effective medium theory

polarization-selective devices

Modelo de Anderson para duas impurezas : metodo dos campos efetivos / The two-impurity Anderson model : an effective medium approach

Chaves Neto, Antonio Maia de Jesus

11 May 2004

Orientadores: Roberto Eugenio Lagos Monaco, Guillermo Gerardo Cabrera Oyarzun / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Fisica Gleb Wataghin / Made available in DSpace on 2018-08-04T08:16:12Z (GMT). No. of bitstreams: 1 ChavesNeto_AntonioMaiadeJesus_D.pdf: 1164069 bytes, checksum: a0ef564c6eb492fa671d7430fad4221a (MD5) Previous issue date: 2004 / Resumo: O Hamiltoniano do modelo de Anderson para duas impurezas é estudado via um desacoplamento das funções de Green. Neste caso resulta ser equivalente a aproximação de potencial coerente (CPA) que também, neste caso, coincide com a aproximação Hubbard-I. Consideram-se todos os termos de interação impureza-impureza, tanto os denominados termos de um corpo como os de dois corpos. Os parâmetros associados às interações mencionadas acima incluem: repulsão coulombiana intra e intersítio, hopping direto, hopping correlacionado e o termo de troca (exchange). Todos estes são modelados via orbitais atômicos de Slater, e neste caso se considera o modelo mais simples, o caso não degenerado, ou seja, um nível por impureza. Nesta modelagem, incluindo o metal hospedeiro, os parâmetros independentes resultam ser: a constante de hibridização eletrônica impureza-metal, o número de portadores do metal hospedeiro, o vetor de onda de Fermi associado ao mesmo, a largura dos orbitais atômicos das impurezas e a distância impureza-impureza. Para o caso particular de temperatura nula e no regime denominado de banda semicheia (a metade dos níveis das impurezas são preenchidos considerando os valores esperados) são calculadas as densidades espectrais (densidade de estados) associadas às impurezas, as funções de correlações de spin e carga, suscetibilidades magnéticas e de carga, e a energia de correlação associada as impurezas. Os resultados são discutidos no contexto dos modelos já a existentes na literatura, assim como os casos limites para os quais existem resultados exatos. Os resultados encontrados estão de acordo com os casos limites conhecidos e são interessantes. Mostram também a importância de se considerar todas as interações impureza-impureza, fato negligenciado até agora na literatura / Abstract: We study the two impurity Anderson Model Hamiltonian via a Greens function decoupling scheme. This case turns out to be equivalent to the Coherent Potential Approximation (CPA) and furthermore equivalent to the Hubbard-I approximation. We consider all one and two body impurity-impurity interactions. The parameters associated to the latter include: the intra and intersite Coulomb repulsion, direct (band) hopping, correlated hopping and the exchange term. All of the above are modeled via Slater atomic orbitals, and here we consider the simplest model, non degenerate single impurity level. Including the host metal the resulting independent parameters are: The impurity-metal hybridization constant, the metal host carrier density, the associated Fermi wavevector, the atomic orbital width and the impurity-impurity distance. For the zero temperature case and in the so called band half called regime (impurities levels half called, in the mean) we compute the impurities spectral densities (density of states), spin and charge correlation functions, their respective susceptibilities and the correlation energy. We discuss our results considering the existing literature as well as the exact results for particular limiting cases. Our results agree with the latter and also yield interesting consequences, among others: the importance of including all impurity-impurity interactions, hitherto not considered. / Doutorado / Física da Matéria Condensada / Mestre em Física

Modelo de Anderson para duas impurezas

Kondo, Efeito

Aproximação de potencial coerente

Aproximação média efetiva

Two-impurity Anderson model

Kondo effect

Coherent potential approximation

Effective medium approximation